TLE3 as a marker for chemotherapy

ABSTRACT

Methods of using TLE3 as a marker for predicting the likelihood that a patient&#39;s cancer will respond to chemotherapy. Methods of using TLE3 as a marker for selecting a chemotherapy for a cancer.

CROSS REFERENCE TO RELATED APPLICATION

This application claims priority to U.S. Provisional Patent Application Ser. No. 60/991,487, filed Nov. 30, 2007, the entirety of which is hereby incorporated herein by reference.

BACKGROUND OF THE INVENTION

A major challenge of cancer treatment is the selection of chemotherapies that maximize efficacy and minimize toxicity for a given patient. Assays for cell surface markers, e.g., using immunohistochemistry (IHC), have provided means for dividing certain cancers into subclasses. For example, one factor considered in prognosis and treatment decisions for breast cancer is the presence or absence of the estrogen receptor (ER). ER-positive breast cancers typically respond much more readily to hormonal therapies such as tamoxifen, which acts as an anti-estrogen in breast tissue, than ER-negative cancers. Though useful, these analyses only in part predict the clinical behavior of breast cancers. There is phenotypic diversity present in cancers that current diagnostic tools fail to detect. As a consequence, there is still much controversy over how to stratify patients amongst potential treatments in order to optimize outcome (e.g., for breast cancer see “NIH Consensus Development Conference Statement: Adjuvant Therapy for Breast Cancer, Nov. 1-3, 2000”, J. Nat. Cancer Inst. Monographs, 30:5-15, 2001 and Di Leo et al., Int. J. Clin. Oncol. 7:245-253, 2002). In particular, there is currently no tool for predicting a patient's likely response to treatment with paclitaxel, a chemotherapeutic with particularly adverse side-effects. There clearly exists a need for improved methods and reagents for classifying cancers and thereby selecting therapeutic regimens that maximize efficacy and minimize toxicity for a given patient.

SUMMARY OF THE INVENTION

We have identified a correlation between the expression of TLE3 (transducin-like enhancer of split 3, Entrez Gene ID 7090) and a cancer's response to chemotherapy. This correlation has been demonstrated using TLE3 antibodies and samples from breast cancer cohorts which include both treated and untreated patients with known outcome. The inventors have also observed that binding of TLE3 antibodies in samples from treated ovarian cancer patients correlates with improved prognosis. In one aspect, the present invention therefore provides methods of using TLE3 as a marker for predicting the likelihood that a patient's cancer will respond to chemotherapy. In another aspect, the present invention provides methods of using TLE3 as a marker for deciding whether to administer chemotherapy to a cancer patient. In yet another aspect, the present invention provides methods of using TLE3 as a marker for selecting a chemotherapy for a cancer patient.

Expression of TLE3 can be detected using any known method. Thus, while the inventive methods have been exemplified by detecting TLE3 polypeptides using antibodies, in certain embodiments TLE3 polynucleotides may be detected using one or more primers as is well known in the art.

In general, TLE3 can be used in conjunction with other markers or clinical factors (e.g., stage, tumor size, node characteristics, age, etc.) to further improve the predictive power of the inventive methods.

BRIEF DESCRIPTION OF THE APPENDIX

This patent application refers to material comprising a table and data presented as Appendix A. Specifically, Appendix A is a table that lists a variety of markers that could be used in a panel in conjunction with the TLE3 marker in an inventive method. The table includes the antibody ID, parent gene name, Entrez Gene ID, known aliases for the parent gene, peptides that may be used in preparing antibodies and exemplary antibody titers for staining. Using the parent gene name, Entrez Gene ID and/or known aliases for the parent gene, a skilled person can readily obtain the nucleotide (and corresponding amino acid) sequences for each and every one of the parent genes that are listed in Appendix A from a public database (e.g., GenBank, Swiss-Prot or any future derivative of these). The nucleotide and corresponding amino acid sequences for each and every one of the parent genes that are listed in Appendix A are hereby incorporated by reference from these public databases. Antibodies with IDs that begin with S5 or S6 may be obtained from commercial sources as indicated.

BRIEF DESCRIPTION OF THE DRAWING

FIG. 1 compares IHC images of TLE3-negative (S0643−) and TLE3-positive (S0643+) samples from breast cancer patients.

FIG. 2 shows Kaplan-Meier recurrence curves that were generated using all patients in the Huntsville Hospital (HH) breast cancer cohort after classification based on staining with an antibody raised against the TLE3 marker. Recurrence data from TLE3-positive and TLE3-negative patients were used to generate the top and bottom curves, respectively. As shown in the Figure, antibody binding to the TLE3 marker correlates with improved prognosis across this breast cancer cohort (HR=0.573, p<0.004).

FIG. 3 shows Kaplan-Meier recurrence curves that were generated using all patients in the Roswell Park Cancer Institute (RP) breast cancer cohort after classification based on staining with an antibody raised against the TLE3 marker. The selected patients in the RP cohort were all triple negative for the ER (estrogen receptor, Entrez GeneID 2099), PR (progesterone receptor, Entrez GeneID 5241) and HER-2 markers (v-erb-b2 erythroblastic leukemia viral oncogene homolog 2, Entrez GeneID 2064). Recurrence data from TLE3-positive and TLE3-negative patients were used to generate the top and bottom curves, respectively. As shown in the Figure, antibody binding to the TLE3 marker correlates with improved prognosis across this breast cancer cohort (HR=0.24, p<0.011).

FIG. 4 shows Kaplan-Meier recurrence curves that were generated using patients in the HH breast cancer cohort of FIG. 1 that did not receive chemotherapy. Recurrence data from TLE3-positive and TLE3-negative patients in this subset were used to generate the top and bottom curves, respectively. As shown in the Figure, antibody binding to the TLE3 marker loses its correlation with prognosis in breast cancer patients that did not receive chemotherapy (HR=0.788, p=0.49).

FIG. 5 shows Kaplan-Meier recurrence curves that were generated using patients in the HH breast cancer cohort of FIG. 1 that did receive chemotherapy. Recurrence data from TLE3-positive and TLE3-negative patients in this subset were used to generate the top and bottom curves, respectively. As shown in the Figure, the correlation between antibody binding to the TLE3 marker and prognosis was restored in patients that did receive chemotherapy (HR=0.539, p<0.013).

FIG. 6 shows Kaplan-Meier recurrence curves that were generated using patients in the RP breast cancer cohort of FIG. 2 that did receive chemotherapy. Recurrence data from TLE3-positive and TLE3-negative patients in this subset were used to generate the top and bottom curves, respectively. As shown in the Figure, antibody binding to the TLE3 marker correlates with improved prognosis across this subset of breast cancer patients (HR=0.194, p=0.010). These results parallel those obtained in FIG. 5 with the HH cohort.

FIG. 7 shows Kaplan-Meier recurrence curves that were generated using patients in the HH breast cancer cohort of FIG. 5 that received CMF (cyclophosphamide, methotrexate and 5-fluorouracil) chemotherapy. Recurrence data from TLE3-positive and TLE3-negative patients in this subset were used to generate the top and bottom curves, respectively. As shown in the Figure, antibody binding to the TLE3 marker correlates with improved prognosis across this subset of treated patients (HR=0.398, p<0.019).

FIG. 8 shows Kaplan-Meier recurrence curves that were generated using patients in the HH breast cancer cohort of FIG. 5 that received CA (cyclophosphamide and adriamycin) or CAF (cyclophosphamide, adriamycin and 5-fluorouracil) chemotherapy (with or without a taxane). Recurrence data from TLE3-positive and TLE3-negative patients in this subset were used to generate the top and bottom curves, respectively. As shown in the Figure, the correlation between antibody binding to the TLE3 marker and prognosis loses significance in this subset of treated patients (HR=0.666, p=0.22).

FIG. 9 shows Kaplan-Meier recurrence curves that were generated using patients in the HH breast cancer cohort of FIG. 8 that received CA or CAF chemotherapy only (i.e., without a taxane). Recurrence data from TLE3-positive and TLE3-negative patients in this subset were used to generate the top and bottom curves, respectively. As shown in the Figure, there is no correlation between antibody binding to the TLE3 marker and prognosis in this subset of treated patients (HR=1.03, p=0.95).

FIG. 10 shows Kaplan-Meier recurrence curves that were generated using patients in the HH breast cancer cohort of FIG. 8 that received CA or CAF in combination with a taxane. Recurrence data from TLE3-positive and TLE3-negative patients in this subset were used to generate the top and bottom curves, respectively. As shown in the Figure, the correlation between antibody binding to the TLE3 marker and prognosis was restored in this subset of treated patients (HR=0.114, p=0.038).

FIG. 11 shows Kaplan-Meier recurrence curves that were generated using patients in the RP breast cancer cohort of FIG. 6 that received CA chemotherapy only (i.e., without a taxane). Recurrence data from TLE3-positive and TLE3-negative patients in this subset were used to generate the top and bottom curves, respectively. As shown in the Figure, there is no correlation between antibody binding to the TLE3 marker and prognosis in this subset of treated patients (HR=0.759, p=0.81).

FIG. 12 shows Kaplan-Meier recurrence curves that were generated using patients in the RP breast cancer cohort of FIG. 6 that received CA in combination with a taxane. Recurrence data from TLE3-positive and TLE3-negative patients in this subset were used to generate the top and bottom curves, respectively. As shown in the Figure, antibody binding to the TLE3 marker correlates with improved prognosis across this subset of treated patients (HR=0.142, p=0.011).

FIG. 13 shows Kaplan-Meier recurrence curves that were generated using patients in the RP breast cancer cohort of FIG. 6 that received a taxane or CMF. Some of the patients receiving a taxane also received CA. Recurrence data from TLE3-positive and TLE3-negative patients in this subset were used to generate the top and bottom curves, respectively. As shown in the Figure, antibody binding to the TLE3 marker correlates with improved prognosis across this subset of treated patients (HR=0.137, p=0.011).

FIG. 14 shows Kaplan-Meier recurrence curves that were generated using patients in the RP breast cancer cohort of FIG. 6 that received neoadjuvant chemotherapy. Recurrence data from TLE3-positive and TLE3-negative patients in this subset were used to generate the top and bottom curves, respectively. The sample size was small (N=12); however, as shown in the Figure, antibody binding to the TLE3 marker showed significant correlation with improved prognosis across this subset of treated patients when measured using the Fisher Exact Test (p=0.005).

FIGS. 15-17 show Kaplan-Meier recurrence curves that were generated using patients in the RP breast cancer cohort of FIG. 6 that received chemotherapy. Recurrence data from TLE3-positive and TLE3-negative patients with stage II+ (FIG. 15), stage IIb+ (FIG. 16) and stage III+ (FIG. 17) cancers were used to generate the top and bottom curves, respectively. In each case, antibody binding to the TLE3 marker correlated with improved prognosis across these subsets of treated patients. The sample size was small in the subset of FIG. 17 (N=19); however significance was obtained when measured using the Fisher Exact Test (p=0.020).

FIG. 18 shows Kaplan-Meier recurrence curves that were generated using patients in the University of Alabama at Birmingham (UAB) ovarian cancer cohort. All patients received paclitaxel. Most patients also received platinum chemotherapy (carboplatin or cisplatin). Recurrence data from TLE3-positive and TLE3-negative patients in this subset were used to generate the top and bottom curves, respectively. As shown in the Figure, antibody binding to the TLE3 marker correlated with prognosis in these treated patients (HR=0.64, p<0.049).

DEFINITIONS

Binds—When an interaction partner “binds” a marker they are linked by direct non-covalent interactions.

Cancer markers—“Cancer markers” or “markers” are molecular entities that are detectable in cancer samples. Generally, markers may be polypeptides (e.g., TLE3 protein) or polynucleotides (e.g., TLE3 mRNA) that are indicative of the expression of a gene (e.g., TLE3 gene) and present within the cancer sample, e.g., within the cytoplasm or membranes of cancerous cells and/or secreted from such cells.

Cancer sample—As used herein, the term “cancer sample” or “sample” is taken broadly to include cell or tissue samples removed from a cancer patient (e.g., from a tumor, from the bloodstream, etc.), cells derived from a tumor that may be located elsewhere in the body (e.g., cells in the bloodstream or at a site of metastasis), or any material derived from such a sample. Derived material may include, for example, nucleic acids or proteins extracted from the sample, cell progeny, etc. In one embodiment, a cancer sample may be a tumor sample.

Correlation—“Correlation” refers to the degree to which one variable can be predicted from another variable, e.g., the degree to which a cancer's response to therapy can be predicted from the expression of a marker in a cancer sample. A variety of statistical methods may be used to measure correlation between two variables, e.g., without limitation the student t-test, the Fisher exact test, the Pearson correlation coefficient, the Spearman correlation coefficient, the Chi squared test, etc. Results are traditionally given as a measured correlation coefficient with a p-value that provides a measure of the likelihood that the correlation arose by chance. A correlation with a p-value that is less than 0.05 is generally considered to be statistically significant. Preferred correlations have p-values that are less than 0.01, especially less than 0.001.

Hybridized—When a primer and a marker are physically “hybridized” with one another as described herein, they are non-covalently linked by base pair interactions.

Interaction partner—An “interaction partner” is an entity that binds a polypeptide marker. For example and without limitation, an interaction partner may be an antibody or a fragment thereof that binds a marker. In general, an interaction partner is said to “bind specifically” with a marker if it binds at a detectable level with the marker and does not bind detectably with unrelated molecular entities (e.g., other markers) under similar conditions. Specific association between a marker and an interaction partner will typically be dependent upon the presence of a particular structural feature of the target marker such as an antigenic determinant or epitope recognized by the interaction partner. In general, it is to be understood that specificity need not be absolute. For example, it is well known in the art that antibodies frequently cross-react with other epitopes in addition to the target epitope. Such cross-reactivity may be acceptable depending upon the application for which the interaction partner is to be used. Thus the degree of specificity of an interaction partner will depend on the context in which it is being used. In general, an interaction partner exhibits specificity for a particular marker if it favors binding with that partner above binding with other potential partners, e.g., other markers. One of ordinary skill in the art will be able to select interaction partners having a sufficient degree of specificity to perform appropriately in any given application (e.g., for detection of a target marker, for therapeutic purposes, etc.). It is also to be understood that specificity may be evaluated in the context of additional factors such as the affinity of the interaction partner for the target marker versus the affinity of the interaction partner for other potential partners, e.g., other markers. If an interaction partner exhibits a high affinity for a target marker and low affinity for non-target molecules, the interaction partner will likely be an acceptable reagent for diagnostic purposes even if it lacks specificity.

Primer—A “primer” is an oligonucleotide entity that physically hybridizes with a polynucleotide marker. In general, a primer is said to “hybridize specifically” with a marker if it hybridizes at a detectable level with the marker and does not hybridize detectably with unrelated molecular entities (e.g., other markers) under similar conditions. Specific hybridization between a marker and a primer will typically be dependent upon the presence of a particular nucleotide sequence of the target marker which is complementary to the nucleotide sequence of the primer. In general, it is to be understood that specificity need not be absolute. The degree of specificity of a primer will depend on the context in which it is being used. In general, a primer exhibits specificity for a particular marker if it favors hybridization with that partner above hybridization with other potential partners, e.g., other markers. One of ordinary skill in the art will be able to select primers having a sufficient degree of specificity to perform appropriately in any given application. It is also to be understood that specificity may be evaluated in the context of additional factors such as the affinity of the primer for the target marker versus the affinity of the primer for other potential partners, e.g., other markers. If a primer exhibits a high affinity for a target marker and low affinity for non-target molecules, the primer will likely be an acceptable reagent for diagnostic purposes even if it lacks specificity.

Response—The “response” of a cancer to therapy may represent any detectable change, for example at the molecular, cellular, organellar, or organismal level. For instance, tumor size, patient life expectancy, recurrence, or the length of time the patient survives, etc., are all responses. Responses can be measured in any of a variety of ways, including for example non-invasive measuring of tumor size (e.g., CT scan, image-enhanced visualization, etc.), invasive measuring of tumor size (e.g., residual tumor resection, etc.), surrogate marker measurement (e.g., serum PSA, etc.), clinical course variance (e.g., measurement of patient quality of life, time to relapse, survival time, etc.). Small molecule—A “small molecule” is a non-polymeric molecule. A small molecule can be synthesized in a laboratory (e.g., by combinatorial synthesis) or found in nature (e.g., a natural product). A small molecule is typically characterized in that it contains several carbon-carbon bonds and has a molecular weight of less than about 1500 Da, although this characterization is not intended to be limiting for the purposes of the present invention.

DETAILED DESCRIPTION OF CERTAIN PREFERRED EMBODIMENTS OF THE INVENTION

As noted above, we have identified a correlation between the expression of TLE3 (transducin-like enhancer of split 3, Entrez Gene ID 7090) in a cancer sample and a cancer's response to chemotherapy. As described in the Examples, this correlation has been demonstrated using TLE3 antibodies and samples from two breast cancer cohorts which include both treated and untreated patients with known outcome. We have also shown that this predictive model is consistent when applied to samples from a cohort of treated ovarian cancer patients. We have also demonstrated the utility of TLE3 for predicting response to specific types of chemotherapies including treatments which involve the administration of cell cycle specific chemotherapeutics, e.g., methotrexate and taxanes. Since these chemotherapeutics have known utility across different cancer types, these results suggest that the inventive methods will also be useful in predicting their efficacy across different cancer types.

Predicting Response to Chemotherapy and Selecting Chemotherapy

In one aspect, the present invention provides methods of using TLE3 as a marker for predicting the likelihood that a patient's cancer will respond to chemotherapy. In general, these methods involve providing a cancer sample from a cancer patient, determining whether TLE3 is expressed in the cancer sample, and predicting the likelihood that the patient's cancer will respond to chemotherapy based upon a result of the step of determining. In one embodiment, the step of predicting comprises predicting that the patient's cancer is likely to respond to chemotherapy based upon the presence of TLE3 expression in the cancer sample. In one embodiment, the step of predicting comprises predicting that the patient's cancer is unlikely to respond to chemotherapy based upon the absence of TLE3 expression in the cancer sample.

In certain embodiments, a negative control sample is provided and the step of determining comprises detecting a level of TLE3 expression in the cancer sample and the negative control sample and comparing the level of expression of TLE3 in the cancer sample and the negative control sample. In general, the negative control sample can be any sample that does not reproducibly express TLE3. In one embodiment, the negative control sample can be a sample that does not reproducibly bind TLE3 antibodies. In one embodiment, the negative control sample can be a sample that does not reproducibly produce a detectable level of TLE3 mRNA. In one embodiment, the negative control sample can be from a patient with a TLE3-negative cancer. In one embodiment, the negative control sample can be from a patient without cancer. In certain embodiments the negative control sample may originate from the same tissue type as the cancer in question (e.g., breast tissue when considering breast cancer). In other embodiments, the negative control sample may originate from a different tissue type or even a different organism, or a cell line.

Additionally or alternatively, in certain embodiments, a positive control sample is provided and the step of determining comprises detecting a level of TLE3 expression in the cancer sample and the positive control sample and comparing the level of expression of TLE3 in the cancer sample and the positive control sample. In general, the positive control sample can be any sample that reproducibly expresses TLE3. In one embodiment, the negative control sample can be a sample that reproducibly bind TLE3 antibodies. In one embodiment, the negative control sample can be a sample that reproducibly produces a detectable level of TLE3 mRNA. In one embodiment, the positive control sample can be from a patient with a TLE3-positive cancer. In certain embodiments the positive control sample may originate from the same tissue type as the cancer in question (e.g., breast tissue when considering breast cancer). In other embodiments, the positive control sample may originate from a different tissue type or even a different organism, or cell line.

Expression of TLE3 can be determined using any known method.

In one embodiment, TLE3 polypeptides may be detected using an interaction partner that binds a TLE3 polypeptide (e.g., TLE3 protein or an antigenic fragment thereof). For example, as described below one may use a TLE3 antibody as an interaction partner and detect TLE3 expression by contacting the cancer sample with the TLE3 antibody. In such embodiments, the inventive methods may involve providing a cancer sample from a cancer patient, contacting the cancer sample with an antibody directed to TLE3, and predicting the likelihood that the patient's cancer will respond to chemotherapy based upon binding of the antibody to the cancer sample. In one embodiment, the step of predicting may comprise predicting that the patient's cancer is likely to respond to chemotherapy based upon binding of the antibody to the cancer sample. In another embodiment, the step of predicting may comprise predicting that the patient's cancer is unlikely to respond to chemotherapy based upon lack of binding of the antibody to the cancer sample.

In another embodiment, TLE3 polynucleotides may be detected using one or more primers that hybridize with a TLE3 polynucleotide (e.g., a TLE3 mRNA, cDNA or RNA). In such embodiments, the inventive methods may involve providing a cancer sample from a cancer patient, contacting the cancer sample with one or more primers that hybridize with TLE3, and predicting the likelihood that the patient's cancer will respond to chemotherapy based upon hybridization of the one or more primers to the cancer sample. In one embodiment, the step of predicting may comprise predicting that the patient's cancer is likely to respond to chemotherapy based upon hybridization of the one or more primers to the cancer sample. In another embodiment, the step of predicting may comprise predicting that the patient's cancer is unlikely to respond to chemotherapy based upon lack of hybridization of the one or more primers to the cancer sample.

In another aspect, the present invention provides methods for deciding whether to administer chemotherapy to the cancer patient based upon the likelihood that the patient's cancer will respond to chemotherapy. In one embodiment, the step of deciding comprises deciding to administer chemotherapy to the cancer patient based upon the presence of TLE3 expression in the cancer sample. In one embodiment, the step of deciding comprises deciding not to administer chemotherapy to the cancer patient based upon the absence of TLE3 expression in the cancer sample.

In yet another aspect, the present invention provides methods for selecting a chemotherapy for a cancer patient. In general, these methods comprise providing a cancer sample from a cancer patient, determining whether TLE3 is expressed in the cancer sample, and selecting a chemotherapy for the cancer patient based upon the results of the step of determining. In one embodiment, the step of selecting comprises selecting a chemotherapy based upon the presence of TLE3 expression in the cancer sample.

As described in the Examples, we have demonstrated that TLE3 expression correlates with response to chemotherapy with methotrexate (see FIG. 7) and taxanes (see FIGS. 10, 12 and 13). Methotrexate and taxanes are thought to be cell cycle specific chemotherapeutics (e.g., see Goodman & Gilman's The Pharmacological Basis of Therapeutics, IX. Chemotherapy of Neoplastic Diseases Chapter 51. Antineoplastic Agents, 11th Edition, Laurence L. Brunton, editor-in-chief, John S. Lazo and Keith L. Parker, Associate Editors). Cell cycle specific chemotherapeutics exhibit their mechanism of action within a specific phase of the cell cycle in contrast to non-cell cycle specific chemotherapeutics that work equally with all phases including the resting phase (G0). Other plant alkaloids besides the taxanes have also been classified in the literature as cell cycle specific chemotherapeutics as have other antimetabolites besides methotrexate. In contrast, many alkylating agents such as cisplatin and cyclophosamide have been classified as non-cell cycle specific chemotherapeutics. Our results suggest that the predictive power of TLE3 may extend to other cell cycle specific chemotherapeutics besides methotrexate and taxanes.

In some embodiments, the inventive methods may therefore be used to select, or decide whether to administer, a cell cycle specific chemotherapeutic. In one embodiment, the inventive methods may be used to select, or decide whether to administer, an antimetabolite. In one embodiment, the inventive methods may be used to select, or decide whether to administer, a plant alkaloid. In one embodiment, the inventive methods may be used to select, or decide whether to administer, methotrexate. In another embodiment, the inventive methods may be used to select, or decide whether to administer, a taxane. In one embodiment the taxane is paclitaxel. In one embodiment the taxane is docetaxel.

In each case it will be appreciated that these chemotherapeutics may be administered alone or in combination with other chemotherapeutics as is known in the art and discussed below. It will also be appreciated that the present invention encompasses methods in which the selected chemotherapeutic is a methotrexate or taxane derivative, i.e., a compound with a structure which is derived from methotrexate or a taxane. Derivatives will typically share most of the structure of the parent compound but may include different substituents, heteroatoms, ring fusions, levels of saturation, isomerism, stereoisomerism, etc. at one or more positions within the parent compound. Without limitation, the following U.S. patents describe the preparation of exemplary methotrexate derivatives that could be employed according to an inventive method: U.S. Pat. Nos. 6,559,149 and 4,374,987. Without limitation, the following U.S. patents describe the preparation of exemplary taxane derivatives that could be employed according to an inventive method: U.S. Pat. Nos. 7,074,945; 7,063,977; 6,906,101; 6,649,778; 6,596,880; 6,552,205; 6,531,611; 6,482,963; 6,482,850; 6,462,208; 6,455,575; 6,441,026; 6,433,180; 6,392,063; 6,369,244; 6,339,164; 6,291,690; 6,268,381; 6,239,167; 6,218,553; 6,214,863; 6,201,140; 6,191,290; 6,187,916; 6,162,920; 6,147,234; 6,136,808; 6,114,550; 6,107,332; 6,051,600; 6,025,385; 6,011,056; 5,955,489; 5,939,567; 5,912,263; 5,908,835; 5,869,680; 5,861,515; 5,821,263; 5,763,477; 5,750,561; 5,728,687; 5,726,346; 5,726,318; 5,721,268; 5,719,177; 5,714,513; 5,714,512; 5,703,117; 5,698,582; 5,686,623; 5,677,462; 5,646,176; 5,637,723; 5,621,121; 5,616,739; 5,606,083; 5,580,899; 5,476,954; 5,403,858; 5,380,916; 5,254,703; and 5,250,722. The entire contents of each of the aforementioned patents and any other reference which is cited herein is hereby incorporated by reference.

Methotrexate acts by inhibiting the metabolism of folic acid and has been approved for the treatment of bladder cancer, breast cancer, gastric cancer, choriocarcinoma, head and neck cancer, leptomeningeal cancer, leukemia (acute meningeal, acute lymphoblastic, acute lymphocytic), lymphoma (Burkitt's, childhood, non-Hodgkin's), mycosis fungoides, primary unknown cancer and lymphatic sarcoma (Methotrexate in BC Cancer Agency Cancer Drug Manual, 2007). Methotrexate has also been shown to be useful for treating esophageal cancer, lung cancer and testicular cancer (Methotrexate in UpToDate, 2007). In certain embodiments, the inventive methods comprise a step of selecting, or deciding whether to administer, methotrexate in combination with one or more additional chemotherapeutics. For example, methotrexate is commonly administered to cancer patients as a combination called CMF which also includes cyclophosphamide and 5-fluorouracil.

Taxanes are diterpenes produced by the plants of the genus Taxus. Taxanes can be obtained from natural sources or produced synthetically. Taxanes include paclitaxel (TAXOL™) and docetaxel (TAXOTERE™). Taxanes work by interfering with normal microtubule growth during cell division. In certain embodiments, the inventive methods comprise a step of selecting, or deciding whether to administer, a taxane (e.g., paclitaxel or docetaxel) in combination with one or more additional chemotherapeutics. For example, taxanes are commonly administered to cancer patients in combination with cyclophosphamide and adriamycin (doxorubicin) and optionally 5-fluorouracil (i.e., with CA or CAF).

Paclitaxel has been approved for the treatment of breast cancer, Kaposi's sarcoma, lung cancer and ovarian cancer (Paclitaxel in BC Cancer Agency Cancer Drug Manual, 2007 and Mekhail and Markman, Expert Opin. Pharmacother. 3:755-66, 2002). Paclitaxel has also been shown to be useful in treating cervical cancer (pp. 1124-34 in AHFS 2005 Drug Information. Bethesda, Md.: American Society of Health-System Pharmacists, 2005), endometrial cancer (Paclitaxel in BC Cancer Agency Cancer Drug Manual, 2007), bladder cancer (Paclitaxel in UpToDate, 2007), head and neck cancer (Paclitaxel in UpToDate, 2007), leukemia (Paclitaxel in UpToDate, 2007) and malignant melanoma (Paclitaxel in UpToDate, 2007). Side effects of paclitaxel include hypersensitivity reactions such as flushing of the face, skin rash, or shortness of breath. Patients often receive medication to prevent hypersensitivity reactions before they take paclitaxel. Paclitaxel can also cause temporary damage to the bone marrow. Bone marrow damage can cause a person to be more susceptible to infection, anemia, and bruise or bleed easily. Other side effects may include joint or muscle pain in the arms or legs; diarrhea; nausea and vomiting; numbness, burning, or tingling in the hands or feet; and loss of hair.

Docetaxel has been approved for the treatment of breast cancer (Aapro, Seminars in Oncology 25(5 Suppl 12):7-11, 1998; Nabholtz et al., Journal of Clinical Oncology 17(5):1413-24, 1999; Sjostrom et al., European Journal of Cancer 35(8):1194-201, 1999; and Burstein et al., Journal of Clinical Oncology 18(6):1212-9, 2000), non-small cell lung cancer (Fossella et al., Journal of Clinical Oncology 18(12):2354-62, 2000 and Hainsworth et al., Cancer 89(2):328-33, 2000) and ovarian cancer (Kaye et al., European Journal of Cancer 33(13):2167-70, 1997). Docetaxel has also been shown to be useful in treating esothelioma (Vorobiof et al., Proc Am Soc Clin Oncol 19:578a, 2000), prostate cancer (Picus et al., Seminars in Oncology 26(5 Suppl 17):14-8, 1999 and Petrylak et al., Journal of Clinical Oncology 17(3):958-67, 1999), urothelial transitional cell cancer (Dimopoulos et al., Annals of Oncology 10(11): 1385-8, 1999 and Pectasides et al., European Journal of Cancer 36(1):74-9, 2000), head and neck cancer (Docetaxel in USP DI, 2000 and Couteau et al., British Journal of Cancer 81(3):457-62, 1999) and small cell lung cancer (Smyth et al., European Journal of Cancer 30A(8):1058-60, 1994).

Our observation that improved response to chemotherapy is observed for both breast and ovarian cancer patients that are TLE3-positive suggests that the inventive methods may be useful across different cancer types. Our observation that TLE3 expression is associated with improved response to treatment with methotrexate and taxanes further suggest that the inventive methods may be applicable across cancers that respond to these chemotherapeutics. As discussed above, this includes without limitation breast cancer, ovarian cancer, lung cancer, bladder cancer, gastric cancer, head and neck cancer, and leukemia.

In one embodiment, the inventive methods may be used with a cancer patient that has breast cancer. In one embodiment, the inventive methods may be used with a cancer patient that has ovarian cancer. In one embodiment, the inventive methods may be used with a cancer patient that has lung cancer. In one embodiment, the inventive methods may be used with a cancer patient that has bladder cancer. In one embodiment, the inventive methods may be used with a cancer patient that has gastric cancer. In one embodiment, the inventive methods may be used with a cancer patient that has head and neck cancer. In one embodiment, the inventive methods may be used with a cancer patient that has leukemia.

As demonstrated in the Examples, in one embodiment, the correlation between TLE3 expression and response to chemotherapy was observed with breast cancer patients that are triple negative for the ER (estrogen receptor, Entrez GeneID 2099), PR (progesterone receptor, Entrez GeneID 5241) and HER-2 markers (v-erb-b2 erythroblastic leukemia viral oncogene homolog 2, Entrez GeneID 2064). In certain embodiments, the inventive methods may therefore be used with breast cancer patients that belong to this class.

As demonstrated in the Examples, the correlation between TLE3 expression and response to chemotherapy was found to also exist when treatment was administered in a neoadjuvant setting. Thus, in certain embodiments, the inventive methods may be used with patients receiving chemotherapy in a neoadjuvant setting. In other embodiments, the chemotherapy may be administered in an adjuvant setting.

As demonstrated in the Examples, the correlation between TLE3 expression and response to chemotherapy was also found to be independent of stage. Thus, in certain embodiments, the inventive methods may be used with patients with a stage II+ (i.e., stage II or greater) cancer. In certain embodiments, the inventive methods may be used with patients with a stage IIb+ or a stage III+ cancer.

Detecting TLE3 Expression

As mentioned above, expression of TLE3 can be determined using any known method. In one embodiment, TLE3 expression may be determined by detecting TLE3 polypeptide markers using interaction partners (e.g., antibodies). In another embodiment, TLE3 expression may be determined by detecting TLE3 polynucleotide markers using primers.

Detecting TLE3 Polypeptide Markers TLE3 polypeptide markers may be detected using any interaction partner that binds a TLE3 polypeptide marker (which could be a TLE3 protein or an antigenic fragment thereof). Thus, any entity that binds detectably to the TLE3 marker may be utilized as an interaction partner in accordance with the present invention, so long as it binds the marker with an appropriate combination of affinity and specificity.

Particularly preferred interaction partners are antibodies, or fragments (e.g., F(ab) fragments, F(ab′)₂ fragments, Fv fragments, or sFv fragments, etc.; see, for example, Inbar et al., Proc. Nat. Acad. Sci. USA 69:2659, 1972; Hochman et al., Biochem. 15:2706, 1976; and Ehrlich et al., Biochem. 19:4091, 1980; Huston et al., Proc. Nat. Acad. Sci. USA 85:5879, 1998; U.S. Pat. Nos. 5,091,513 and 5,132,405 to Huston et al.; and U.S. Pat. No. 4,946,778 to Ladner et al., each of which is incorporated herein by reference). In certain embodiments, interaction partners may be selected from libraries of mutant antibodies (or fragments thereof). For example, collections of antibodies that each include different point mutations may be screened for their association with a marker of interest. Yet further, chimeric antibodies may be used as interaction partners, e.g., “humanized” or “veneered” antibodies as described in greater detail below.

When antibodies are used as interaction partners, these may be prepared by any of a variety of techniques known to those of ordinary skill in the art (e.g., see Harlow and Lane, Antibodies: A Laboratory Manual, Cold Spring Harbor Laboratory, 1988, see also the Examples). For example, antibodies can be produced by cell culture techniques, including the generation of monoclonal antibodies, or via transfection of antibody genes into suitable bacterial or mammalian cell hosts, in order to allow for the production of recombinant antibodies. In one technique, an “immunogen” comprising an antigenic portion of a marker of interest (or the marker itself) is initially injected into any of a wide variety of mammals (e.g., mice, rats, rabbits, sheep or goats). In this step, a marker (or an antigenic portion thereof) may serve as the immunogen without modification. Alternatively, particularly for relatively short markers, a superior immune response may be elicited if the marker is joined to a carrier protein, such as bovine serum albumin or keyhole limpet hemocyanin (KLH). The immunogen is injected into the animal host, preferably according to a predetermined schedule incorporating one or more booster immunizations and the animals are bled periodically. Polyclonal antibodies specific for the marker may then be purified from such antisera by, for example, affinity chromatography using the marker (or an antigenic portion thereof) coupled to a suitable solid support. An exemplary method is described in the Examples.

If desired for diagnostic or therapeutic purposes, monoclonal antibodies specific for TLE3 may be prepared, for example, using the technique of Kohler and Milstein, Eur. J. Immunol. 6:511, 1976 and improvements thereto. Briefly, these methods involve the preparation of immortal cell lines capable of producing antibodies having the desired specificity (i.e., reactivity with the marker of interest). Such cell lines may be produced, for example, from spleen cells obtained from an animal immunized as described above. The spleen cells are then immortalized by, for example, fusion with a myeloma cell fusion partner, preferably one that is syngeneic with the immunized animal. A variety of fusion techniques may be employed. For example, the spleen cells and myeloma cells may be combined with a nonionic detergent for a few minutes and then plated at low density on a selective medium that supports the growth of hybrid cells, but not myeloma cells. A preferred selection technique uses HAT (hypoxanthine, aminopterin, thymidine) selection. After a sufficient time, usually about 1 to 2 weeks, colonies of hybrids are observed. Single colonies are selected and their culture supernatants tested for binding activity against the marker. Hybridomas having high reactivity and specificity are preferred.

Monoclonal antibodies may be isolated from the supernatants of growing hybridoma colonies. In addition, various techniques may be employed to enhance the yield, such as injection of the hybridoma cell line into the peritoneal cavity of a suitable vertebrate host, such as a mouse. Monoclonal antibodies may then be harvested from the ascites fluid or the blood. Contaminants may be removed from the antibodies by conventional techniques, such as chromatography, gel filtration, precipitation and extraction. TLE3 may be used in the purification process in, for example, an affinity chromatography step.

It is to be understood that the present invention is not limited to using antibodies or antibody fragments as interaction partners. In particular, the present invention also encompasses the use of synthetic interaction partners that mimic the functions of antibodies. Several approaches to designing and/or identifying antibody mimics have been proposed and demonstrated (e.g., see the reviews by Hsieh-Wilson et al., Acc. Chem. Res. 29:164, 2000 and Peczuh and Hamilton, Chem. Rev. 100:2479, 2000). For example, small molecules that bind protein surfaces in a fashion similar to that of natural proteins have been identified by screening synthetic libraries of small molecules or natural product isolates (e.g., see Gallop et al., J. Med. Chem. 37:1233, 1994; Gordon et al., J. Med. Chem. 37:1385, 1994; DeWitt et al., Proc. Natl. Acad. Sci. U.S.A. 90:6909, 1993; Bunin et al., Proc. Natl. Acad. Sci. U.S.A. 91:4708, 1994; Virgilio and Ellman, J. Am. Chem. Soc. 116:11580, 1994; Wang et al., J. Med. Chem. 38:2995, 1995; and Kick and Ellman, J. Med. Chem. 38:1427, 1995). Similarly, combinatorial approaches have been successfully applied to screen libraries of peptides and proteins for their ability to bind arange of proteins (e.g., see Cull et al., Proc. Natl. Acad. Sci. U.S.A. 89:1865, 1992; Mattheakis et al., Proc. Natl. Acad. Sci. U.S.A. 91:9022, 1994; Scott and Smith, Science 249:386, 1990; Devlin et al., Science 249:404, 1990; Corey et al., Gene 128:129, 1993; Bray et al., Tetrahedron Lett. 31:5811, 1990; Fodor et al., Science 251:767, 1991; Houghten et al., Nature 354:84, 1991; Lam et al., Nature 354:82, 1991; Blake and Litzi-Davis, Bioconjugate Chem. 3:510, 1992; Needels et al., Proc. Natl. Acad. Sci. U.S.A. 90:10700, 1993; and Ohlmeyer et al., Proc. Natl. Acad. Sci. U.S.A. 90:10922, 1993). Similar approaches have also been used to study carbohydrate-protein interactions (e.g., see Oldenburg et al., Proc. Natl. Acad. Sci. U.S.A. 89:5393, 1992) and polynucleotide-protein interactions (e.g., see Ellington and Szostak, Nature 346:818, 1990 and Tuerk and Gold, Science 249:505, 1990). These approaches have also been extended to study interactions between proteins and unnatural biopolymers such as oligocarbamates, oligoureas, oligosulfones, etc. (e.g., see Zuckermann et al., J. Am. Chem. Soc. 114:10646, 1992; Simon et al., Proc. Natl. Acad. Sci. U.S.A. 89:9367, 1992; Zuckermann et al., J. Med. Chem. 37:2678, 1994; Burgess et al., Angew. Chem., Int. Ed. Engl. 34:907, 1995; and Cho et al., Science 261:1303, 1993). Yet further, alternative protein scaffolds that are loosely based around the basic fold of antibody molecules have been suggested and may be used in the preparation of inventive interaction partners (e.g., see Ku and Schultz Proc. Natl. Acad. Sci. U.S.A. 92:6552, 1995). Antibody mimics comprising a scaffold of a small molecule such as 3-aminomethylbenzoic acid and a substituent consisting of a single peptide loop have also been constructed. The peptide loop performs the binding function in these mimics (e.g., see Smythe et al., J. Am. Chem. Soc. 116:2725, 1994). A synthetic antibody mimic comprising multiple peptide loops built around a calixarene unit has also been described (e.g., see U.S. Pat. No. 5,770,380 to Hamilton et al.).

Any available strategy or system may be utilized to detect association between an interaction partner and the TLE3 marker. In certain embodiments, association can be detected by adding a detectable label to the interaction partner. In other embodiments, association can be detected by using a labeled secondary interaction partner that binds specifically with the primary interaction partner, e.g., as is well known in the art of antigen/antibody detection. The detectable label may be directly detectable or indirectly detectable, e.g., through combined action with one or more additional members of a signal producing system. Examples of directly detectable labels include radioactive, paramagnetic, fluorescent, light scattering, absorptive and calorimetric labels. Examples of indirectly detectable include chemiluminescent labels, e.g., enzymes that are capable of converting a substrate to a chromogenic product such as alkaline phosphatase, horseradish peroxidase and the like.

Once a labeled interaction partner has bound the TLE3 marker, the complex may be visualized or detected in a variety of ways, with the particular manner of detection being chosen based on the particular detectable label, where representative detection means include, e.g., scintillation counting, autoradiography, measurement of paramagnetism, fluorescence measurement, light absorption measurement, measurement of light scattering and the like.

In general, association between an interaction partner and the TLE3 marker may be assayed by contacting the interaction partner with a cancer sample that includes the marker. Depending upon the nature of the sample, appropriate methods include, but are not limited to, immunohistochemistry (IHC), radioimmunoassay, ELISA, immunoblotting and fluorescence activates cell sorting (FACS). In the case where the protein is to be detected in a tissue sample, e.g., a biopsy sample, IHC is a particularly appropriate detection method. Techniques for obtaining tissue and cell samples and performing IHC and FACS are well known in the art.

Where large numbers of samples are to be handled (e.g., when simultaneously analyzing several samples from the same patient or samples from different patients), it may be desirable to utilize arrayed and/or automated formats. In certain embodiments, tissue arrays as described in the Examples may be used. Tissue arrays may be constructed according to a variety of techniques. According to one procedure, a commercially-available mechanical device (e.g., the manual tissue arrayer MTA1 from Beecher Instruments of Sun Prairie, Wis.) is used to remove an 0.6-micron-diameter, full thickness “core” from a paraffin block (the donor block) prepared from each patient, and to insert the core into a separate paraffin block (the recipient block) in a designated location on a grid. In preferred embodiments, cores from as many as about 400 patients (or multiple cores from the same patient) can be inserted into a single recipient block; preferably, core-to-core spacing is approximately 1 mm. The resulting tissue array may be processed into thin sections for staining with interaction partners according to standard methods applicable to paraffin embedded material.

Whatever the format, and whatever the detection strategy, identification of a discriminating titer can simplify binding studies to assess the desirability of using an interaction partner. In such studies, the interaction partner is contacted with a plurality of different samples that preferably have at least one common trait (e.g., tissue of origin), and often have multiple common traits (e.g., tissue of origin, stage, microscopic characteristics, etc.). In some cases, it will be desirable to select a group of samples with at least one common trait and at least one different trait, so that a titer is determined that distinguishes the different trait. In other cases, it will be desirable to select a group of samples with no detectable different traits, so that a titer is determined that distinguishes among previously indistinguishable samples. Those of ordinary skill in the art will understand, however, that the present invention often will allow both of these goals to be accomplished even in studies of sample collections with varying degrees of similarity and difference.

As discussed above and in the Examples, the inventors have applied these techniques to samples from breast and ovarian cancer patients. The invention also encompasses the recognition that markers that are secreted from the cells in which they are produced may be present in serum, enabling their detection through a blood test rather than requiring a biopsy specimen. An interaction partner that binds to such markers represents a particularly preferred embodiment of the invention.

In general, the results of such an assay can be presented in any of a variety of formats. The results can be presented in a qualitative fashion. For example, the test report may indicate only whether or not the TLE3 marker was detected, perhaps also with an indication of the limits of detection. Additionally the test report may indicate the subcellular location of binding, e.g., nuclear versus cytoplasmic and/or the relative levels of binding in these different subcellular locations. The results may be presented in a semi-quantitative fashion. For example, various ranges may be defined and the ranges may be assigned a score (e.g., 0 to 5) that provides a certain degree of quantitative information. Such a score may reflect various factors, e.g., the number of cells in which the marker is detected, the intensity of the signal (which may indicate the level of expression of the marker), etc. The results may be presented in a quantitative fashion, e.g., as a percentage of cells in which the marker is detected, as a concentration, etc. As will be appreciated by one of ordinary skill in the art, the type of output provided by a test will vary depending upon the technical limitations of the test and the biological significance associated with detection of the marker. For example, in certain circumstances a purely qualitative output (e.g., whether or not the marker is detected at a certain detection level) provides significant information. In other cases a more quantitative output (e.g., a ratio of the level of expression of the marker in two samples) is necessary.

Detecting TLE3 Polynucleotide Markers

Although in many cases detection of polypeptide markers using interaction partners such as antibodies may represent the most convenient means of determining whether TLE3 is expressed in a particular sample, the inventive methods also encompass the use of primers for the detection of polynucleotide markers. A variety of methods for detecting the presence of a particular polynucleotide marker are known in the art and may be used in the inventive methods. In general, these methods rely on hybridization between one or more primers and the polynucleotide marker.

Any available strategy or system may be utilized to detect hybridization between primers and the TLE3 polynucleotides (which could be a TLE3 mRNA, a cDNA produced by RT-PCR from mRNA, RNA produced from such cDNA, etc.). In certain embodiments, hybridization can be detected by simply adding a detectable label to the primer. In other embodiments, hybridization can be detected by using a labeled secondary primer that hybridizes specifically with the primary primer (e.g., a region of the primary primer that does not hybridize with the TLE3 marker). In yet other embodiments it may be advantageous to amplify the TLE3 marker within the cancer sample by PCR using a set of primers designed to amplify a region of the TLE3 gene. The resulting product can then be detected, e.g., using a labeled secondary primer that hybridizes with the amplified product. Those skilled in the art will appreciate variations on these embodiments.

Considerations for primer design are well known in the art and are described, for example, in Newton, et al. (eds.) PCR: Essential data Series, John Wiley & Sons; PCR Primer: A Laboratory Manual, Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y., 1995; White, et al. (eds.) PCR Protocols: Current methods and Applications, Methods in Molecular Biology, The Humana Press, Totowa, N.J., 1993. In addition, a variety of computer programs known in the art may be used to select appropriate primers.

In general, a detectable label may be directly detectable or indirectly detectable, e.g., through combined action with one or more additional members of a signal producing system. Examples of directly detectable labels include radioactive, paramagnetic, fluorescent, light scattering, absorptive and calorimetric labels. Examples of indirectly detectable include chemiluminescent labels, e.g., enzymes that are capable of converting a substrate to a chromogenic product such as alkaline phosphatase, horseradish peroxidase and the like.

Once a labeled primer has hybridized with the TLE3 marker, the complex may be visualized or detected in a variety of ways, with the particular manner of detection being chosen based on the particular detectable label, where representative detection means include, e.g., scintillation counting, autoradiography, measurement of paramagnetism, fluorescence measurement, light absorption measurement, measurement of light scattering and the like.

In general, hybridization between a primer and the TLE3 marker may be assayed by contacting the primer with a cancer sample that includes the marker. Depending upon the nature of the cancer sample, appropriate methods include, but are not limited to, microarray analysis, in situ hybridization, Northern blot, and various nucleic acid amplification techniques such as PCR, RT-PCR, quantitative PCR, the ligase chain reaction, etc.

Identification of Novel Therapies

The predictive power of TLE3 is useful according to the present invention not only to classify cancers with respect to their likely responsiveness to known therapies, but also to identify potential new therapies or therapeutic agents that could be useful in the treatment of cancer.

Indeed, TLE3 represents an attractive candidate for identification of new therapeutic agents (e.g., via screens to detect compounds or entities that bind or hybridize to the marker, preferably with at least a specified affinity and/or specificity, and/or via screens to detect compounds or entities that modulate (i.e., increase or decrease) expression, localization, modification, or activity of the marker. Thus, in one embodiment the present invention provides methods comprising steps of contacting a test compound with a cell expressing the TLE3 marker (e.g., individual engineered cells or in the context of a tissue, etc.); and determining whether the test compound modulates the expression, localization, modification, or activity of the TLE3 marker. In many instances, interaction partners or primers (e.g., antisense or RNAi primers) themselves may prove to be useful therapeutics.

Thus the present invention provides interaction partners and primers that are themselves useful therapeutic agents. For example, binding by an antibody raised against TLE3 to cancerous cells might inhibit growth of those cells. Alternatively or additionally, interaction partners defined or prepared according to the present invention could be used to deliver a therapeutic agent to a cancer cell. In particular, interaction partners (e.g., an antibody raised against TLE3) may be coupled to one or more therapeutic agents. Suitable agents in this regard include radionuclides and drugs. Preferred radionuclides include ⁹⁰Y, ¹²³I, ¹²⁵I, ¹³¹I, ¹⁸⁶Re, ¹⁸⁸Re, ²¹¹ At and ²¹²Bi. Preferred drugs include chlorambucil, ifosphamide, meclorethamine, cyclophosphamide, carboplatin, cisplatin, procarbazine, decarbazine, carmustine, cytarabine, hydroxyurea, mercaptopurine, methotrexate, paclitaxel, docetaxel, thioguanine, 5-fluorouracil, actinomycin D, bleomycin, daunorubicin, doxorubicin, etoposide, vinblastine, vincristine, L-asparginase, adrenocorticosteroids, canciclovir triphosphate, adenine arabinonucleoside triphosphate, 5-aziridinyl-4-hydroxylamino-2-nitrobenzamide, acrolein, phosphoramide mustard, 6-methylpurine, etoposide, benzoic acid mustard, cyanide and nitrogen mustard.

According to such embodiments, the therapeutic agent may be coupled with an interaction partner by direct or indirect covalent or non-covalent interactions. A direct interaction between a therapeutic agent and an interaction partner is possible when each possesses a substituent capable of reacting with the other. For example, a nucleophilic group, such as an amino or sulfhydryl group, on one may be capable of reacting with a carbonyl-containing group, such as an anhydride or an acid halide, or with an alkyl group containing a good leaving group (e.g., a halide) on the other. Indirect interactions might involve a linker group that is itself non-covalently bound to both the therapeutic agent and the interaction partner. A linker group can function as a spacer to distance an interaction partner from an agent in order to avoid interference with association capabilities. A linker group can also serve to increase the chemical reactivity of a substituent on an agent or an interaction partner and thus increase the coupling efficiency. An increase in chemical reactivity may also facilitate the use of agents, or functional groups on agents, which otherwise would not be possible.

It will be evident to those skilled in the art that a variety of bifunctional or polyfunctional reagents, both homo- and hetero-functional (such as those described in the catalog of the Pierce Chemical Co., Rockford, Ill.), may be employed as the linker group. Coupling may be effected, for example, through amino groups, carboxyl groups, sulfydryl groups or oxidized carbohydrate residues. There are numerous references describing such methodology, e.g., U.S. Pat. No. 4,671,958, to Rodwell et al. It will further be appreciated that a therapeutic agent and an interaction partner may be coupled via non-covalent interactions, e.g., ligand/receptor type interactions. Any ligand/receptor pair with a sufficient stability and specificity to operate in the context of the invention may be employed to couple a therapeutic agent and an interaction partner. To give but an example, a therapeutic agent may be covalently linked with biotin and an interaction partner with avidin. The strong non-covalent binding of biotin to avidin would then allow for coupling of the therapeutic agent and the interaction partner. Typical ligand/receptor pairs include protein/co-factor and enzyme/substrate pairs. Besides the commonly used biotin/avidin pair, these include without limitation, biotin/streptavidin, digoxigenin/anti-digoxigenin, FK506/FK506-binding protein (FKBP), rapamycin/FKBP, cyclophilin/cyclosporin and glutathione/glutathione transferase pairs. Other suitable ligand/receptor pairs would be recognized by those skilled in the art, e.g., monoclonal antibodies paired with a epitope tag such as, without limitation, glutathione-S-transferase (GST), c-myc, FLAG® and maltose binding protein (MBP) and further those described in Kessler pp. 105-152 of Advances in Mutagenesis” Ed. by Kessler, Springer-Verlag, 1990; “Affinity Chromatography: Methods and Protocols (Methods in Molecular Biology)” Ed. by Pascal Baillon, Humana Press, 2000; and “Immobilized Affinity Ligand Techniques” by Hermanson et al., Academic Press, 1992.

Where a therapeutic agent is more potent when free from the interaction partner, it may be desirable to use a linker group which is cleavable during or upon internalization into a cell. A number of different cleavable linker groups have been described. The mechanisms for the intracellular release of an agent from these linker groups include cleavage by reduction of a disulfide bond (e.g., U.S. Pat. No. 4,489,710 to Spitler), by irradiation of a photolabile bond (e.g., U.S. Pat. No. 4,625,014 to Senter et al.), by hydrolysis of derivatized amino acid side chains (e.g., U.S. Pat. No. 4,638,045 to Kohn et al.), by serum complement-mediated hydrolysis (e.g., U.S. Pat. No. 4,671,958 to Rodwell et al.) and by acid-catalyzed hydrolysis (e.g., U.S. Pat. No. 4,569,789 to Blattler et al.).

In certain embodiments, it may be desirable to couple more than one therapeutic agent to an interaction partner. In one embodiment, multiple molecules of an agent are coupled to one interaction partner molecule. In another embodiment, more than one type of therapeutic agent may be coupled to one interaction partner molecule. Regardless of the particular embodiment, preparations with more than one agent may be prepared in a variety of ways. For example, more than one agent may be coupled directly to an interaction partner molecule, or linkers that provide multiple sites for attachment can be used.

Alternatively, a carrier can be used. A carrier may bear the agents in a variety of ways, including covalent bonding either directly or via a linker group. Suitable carriers include proteins such as albumins (e.g., U.S. Pat. No. 4,507,234 to Kato et al.), peptides, and polysaccharides such as aminodextran (e.g., U.S. Pat. No. 4,699,784 to Shih et al.). A carrier may also bear an agent by non-covalent bonding or by encapsulation, such as within a liposome vesicle (e.g., U.S. Pat. No. 4,429,008 to Martin et al. and U.S. Pat. No. 4,873,088 to Mayhew et al.). Carriers specific for radionuclide agents include radiohalogenated small molecules and chelating compounds. For example, U.S. Pat. No. 4,735,792 to Srivastava discloses representative radiohalogenated small molecules and their synthesis. A radionuclide chelate may be formed from chelating compounds that include those containing nitrogen and sulfur atoms as the donor atoms for binding the metal, or metal oxide, radionuclide. For example, U.S. Pat. No. 4,673,562 to Davison et al. discloses representative chelating compounds and their synthesis.

When interaction partners are themselves therapeutics, it will be understood that, in many cases, any interaction partner that binds the same marker may be so used.

In one preferred embodiment of the invention, the therapeutic agents (whether interaction partners or otherwise) are antibodies, e.g., an antibody against the TLE3 marker. As is well known in the art, when using an antibody or fragment thereof for therapeutic purposes it may prove advantageous to use a “humanized” or “veneered” version of an antibody of interest to reduce any potential immunogenic reaction. In general, “humanized” or “veneered” antibody molecules and fragments thereof minimize unwanted immunological responses toward antihuman antibody molecules which can limit the duration and effectiveness of therapeutic applications of those moieties in human recipients.

A number of “humanized” antibody molecules comprising an antigen binding portion derived from a non-human immunoglobulin have been described in the art, including chimeric antibodies having rodent variable regions and their associated complementarity-determining regions (CDRs) fused to human constant domains (e.g., see Winter et al., Nature 349:293, 1991; Lobuglio et al., Proc. Nat. Acad. Sci. USA 86:4220, 1989; Shaw et al., J. Immunol. 138:4534, 1987; and Brown et al., Cancer Res. 47:3577, 1987), rodent CDRs grafted into a human supporting framework region (FR) prior to fusion with an appropriate human antibody constant domain (e.g., see Riechmann et al., Nature 332:323, 1988; Verhoeyen et al., Science 239:1534, 1988; and Jones et al. Nature 321:522, 1986) and rodent CDRs supported by recombinantly veneered rodent FRs (e.g., see European Patent Publication No. 519,596, published Dec. 23, 1992). It is to be understood that the invention also encompasses “fully human” antibodies produced using the XenoMouse™ technology (AbGenix Corp., Fremont, Calif.) according to the techniques described in U.S. Pat. No. 6,075,181.

Yet further, so-called “veneered” antibodies may be used that include “veneered FRs”. The process of veneering involves selectively replacing FR residues from, e.g., a murine heavy or light chain variable region, with human FR residues in order to provide a xenogeneic molecule comprising an antigen binding portion which retains substantially all of the native FR protein folding structure. Veneering techniques are based on the understanding that the antigen binding characteristics of an antigen binding portion are determined primarily by the structure and relative disposition of the heavy and light chain CDR sets within the antigen-association surface (e.g., see Davies et al., Ann. Rev. Biochem. 59:439, 1990). Thus, antigen association specificity can be preserved in a humanized antibody only wherein the CDR structures, their interaction with each other and their interaction with the rest of the variable region domains are carefully maintained. By using veneering techniques, exterior (e.g., solvent-accessible) FR residues which are readily encountered by the immune system are selectively replaced with human residues to provide a hybrid molecule that comprises either a weakly immunogenic, or substantially non-immunogenic veneered surface.

Preferably, interaction partners suitable for use as therapeutics (or therapeutic agent carriers) exhibit high specificity for the target marker (e.g., TLE3) and low background binding to other markers. In certain embodiments, monoclonal antibodies are preferred for therapeutic purposes.

Pharmaceutical Compositions

As mentioned above, the present invention provides new therapies and methods for identifying these. In certain embodiments, an interaction partner or primer may be a useful therapeutic agent. Alternatively or additionally, interaction partners defined or prepared according to the present invention bind to markers (e.g., TLE3) that serve as targets for therapeutic agents. Also, inventive interaction partners may be used to deliver a therapeutic agent to a cancer cell. For example, interaction partners provided in accordance with the present invention may be coupled to one or more therapeutic agents.

The invention includes pharmaceutical compositions comprising these inventive therapeutic agents. In general, a pharmaceutical composition will include a therapeutic agent in addition to one or more inactive agents such as a sterile, biocompatible carrier including, but not limited to, sterile water, saline, buffered saline, or dextrose solution. The pharmaceutical compositions may be administered either alone or in combination with other therapeutic agents including other chemotherapeutic agents, hormones, vaccines and/or radiation therapy. By “in combination with”, here and elsewhere in the specification, it is not intended to imply that the agents must be administered at the same time or formulated for delivery together, although these methods of delivery are within the scope of the invention. In general, each agent will be administered at a dose and on a time schedule determined for that agent. Additionally, the invention encompasses the delivery of the inventive pharmaceutical compositions in combination with agents that may improve their bioavailability, reduce or modify their metabolism, inhibit their excretion, or modify their distribution within the body. Although the pharmaceutical compositions of the present invention can be used for treatment of any subject (e.g., any animal) in need thereof, they are most preferably used in the treatment of humans.

The pharmaceutical compositions of this invention can be administered to humans and other animals by a variety of routes including oral, intravenous, intramuscular, intra-arterial, subcutaneous, intraventricular, transdermal, rectal, intravaginal, intraperitoneal, topical (as by powders, ointments, or drops), bucal, or as an oral or nasal spray or aerosol. In general the most appropriate route of administration will depend upon a variety of factors including the nature of the agent (e.g., its stability in the environment of the gastrointestinal tract), the condition of the patient (e.g., whether the patient is able to tolerate oral administration), etc. At present the intravenous route is most commonly used to deliver therapeutic antibodies. However, the invention encompasses the delivery of the inventive pharmaceutical composition by any appropriate route taking into consideration likely advances in the sciences of drug delivery.

General considerations in the formulation and manufacture of pharmaceutical agents may be found, for example, in Remington's Pharmaceutical Sciences, 19^(th) ed., Mack Publishing Co., Easton, Pa., 1995.

EXEMPLIFICATION Example 1 Raising Antibodies

This example describes a method that was employed to generate the TLE3 antibodies used in these Examples. Similar methods may be used to generate an antibody that binds to any marker of interest (e.g., to proteins that are or are derived from other markers listed in Appendix A). In some cases, antibodies may be obtained from commercial sources (e.g., Chemicon, Dako, Oncogene Research Products, NeoMarkers, etc.) or other publicly available sources (e.g., Imperial Cancer Research Technology, etc.).

Materials and Solutions

-   -   Anisole (Cat. No. A4405, Sigma, St. Louis, Mo.)     -   2,2′-azino-di-(3-ethyl-benzthiazoline-sulfonic acid) (ABTS)         (Cat. No. A6499, Molecular Probes, Eugene, Oreg.)     -   Activated maleimide Keyhole Limpet Hemocyanin (Cat. No. 77106,         Pierce, Rockford, Ill.)     -   Keyhole Limpet Hemocyanin (Cat. No. 77600, Pierce, Rockford,         Ill.)     -   Phosphoric Acid (H₃PO₄) (Cat. No. P6560, Sigma)     -   Glacial Acetic Acid (Cat No. BP1185-500, Fisher)     -   EDC (EDAC) (Cat No. 341006, Calbiochem)     -   25% Glutaraldehyde (Cat No. G-5882, Sigma)     -   Glycine (Cat No. G-8898, Sigma)     -   Biotin (Cat. No. B2643, Sigma)     -   Boric acid (Cat. No. B0252, Sigma)     -   Sepharose 4B (Cat. No. 17-0120-01, LKB/Pharmacia, Uppsala,         Sweden)     -   Bovine Serum Albumin (LP) (Cat. No. 100 350, Boehringer         Mannheim, Indianapolis, Ind.)     -   Cyanogen bromide (Cat. No. C6388, Sigma)     -   Dialysis tubing Spectra/Por Membrane MWCO: 6-8,000 (Cat. No. 132         665, Spectrum Industries, Laguna Hills, Calif.)     -   Dimethyl formamide (DMF) (Cat. No. 22705-6, Aldrich, Milwaukee,         Wis.)     -   DIC (Cat. No. BP 592-500, Fisher)     -   Ethanedithiol (Cat. No. 39, 802-0, Aldrich)     -   Ether (Cat. No. TX 1275-3, EM Sciences)     -   Ethylenediaminetetraacetatic acid (EDTA) (Cat. No. BP 120-1,         Fisher, Springfield, N.J.)     -   1-ethyl-3-(3′dimethylaminopropyl)-carbodiimide, HCL (EDC) (Cat.         no. 341-006, Calbiochem, San Diego, Calif.)     -   Freund's Adjuvant, complete (Cat. No. M-0638-50B, Lee         Laboratories, Grayson, Ga.)     -   Freund's Adjuvant, incomplete (Cat. No. M-0639-50B, Lee         Laboratories)     -   Fritted chromatography columns (Column part No. 12131011; Frit         Part No. 12131029, Varian Sample Preparation Products, Harbor         City, Calif.)     -   Gelatin from Bovine Skin (Cat. No. G9382, Sigma)     -   Goat anti-rabbit IgG, biotinylated (Cat. No. A 0418, Sigma)     -   HOBt (Cat. No. 01-62-0008, Calbiochem)     -   Horseradish peroxidase (HRP) (Cat. No. 814 393, Boehringer         Mannheim)     -   HRP-Streptavidin (Cat. No. S 5512, Sigma)     -   Hydrochloric Acid (Cat. No. 71445-500, Fisher)     -   Hydrogen Peroxide 30% w/w (Cat. No. H1009, Sigma)     -   Methanol (Cat. No. A412-20, Fisher)     -   Microtiter plates, 96 well (Cat. No. 2595, Corning-Costar,         Pleasanton, Calif.)     -   N-□-Fmoc protected amino acids from Calbiochem. See '97-'98         Catalog pp. 1-45.     -   N-□-Fmoc protected amino acids attached to Wang Resin from         Calbiochem. See '97-'98 Catalog pp. 161-164.     -   NMP (Cat. No. CAS 872-50-4, Burdick and Jackson, Muskegon,         Mich.)     -   Peptide (Synthesized by Research Genetics. Details given below)     -   Piperidine (Cat. No. 80640, Fluka, available through Sigma)     -   Sodium Bicarbonate (Cat. No. BP328-1, Fisher)     -   Sodium Borate (Cat. No. B9876, Sigma)     -   Sodium Carbonate (Cat. No. BP357-1, Fisher)     -   Sodium Chloride (Cat. No. BP 358-10, Fisher)     -   Sodium Hydroxide (Cat. No. SS 255-1, Fisher)     -   Streptavidin (Cat. No. 1 520, Boehringer Mannheim)     -   Thioanisole (Cat. No. T-2765, Sigma)     -   Trifluoroacetic acid (Cat. No. TX 1275-3, EM Sciences)     -   Tween-20 (Cat. No. BP 337-500, Fisher)     -   Wetbox (Rectangular Servin' Saver™ Part No. 3862, Rubbermaid,         Wooster, Ohio)     -   BBS—Borate Buffered Saline with EDTA dissolved in distilled         water (pH 8.2 to 8.4 with HCl or NaOH), 25 mM Sodium borate         (Borax), 100 mM Boric Acid, 75 mM NaCl and 5 mM EDTA.     -   0.1 N HCl in saline as follows: concentrated HCl (8.3 ml/0.917         liter distilled water) and 0.154 M NaCl     -   Glycine (pH 2.0 and pH 3.0) dissolved in distilled water and         adjusted to the desired pH, 0.1 M glycine and 0.154 M NaCl.     -   5× Borate 1× Sodium Chloride dissolved in distilled water, 0.11         M NaCl, 60 mM Sodium Borate and 250 mM Boric Acid.     -   Substrate Buffer in distilled water adjusted to pH 4.0 with         sodium hydroxide, 50 to 100 mM Citric Acid.     -   AA solution: HOBt is dissolved in NMP (8.8 grams HOBt to 1 liter         NMP). Fmoc-N-a-amino at a concentration at 0.53 M.     -   DIC solution: 1 part DIC to 3 parts NMP.     -   Deprotecting solution: 1 part Piperidine to 3 parts DMF.     -   Reagent R: 2 parts anisole, 3 parts ethanedithiol, 5 parts         thioanisole and 90 parts trifluoroacetic acid.         Equipment     -   MRX Plate Reader (Dynatech, Chantilly, Va.)     -   Hamilton Eclipse (Hamilton Instruments, Reno, Nev.)     -   Beckman TJ-6 Centrifuge (Model No. TJ-6, Beckman Instruments,         Fullerton, Calif.)     -   Chart Recorder (Recorder 1 Part No. 18-1001-40, Pharmacia LKB         Biotechnology)     -   UV Monitor (Uvicord SII Part No. 18-1004-50, Pharmacia LKB         Biotechnology)     -   Amicon Stirred Cell Concentrator (Model 8400, Amicon, Beverly,         Mass.)     -   30 kD MW cut-off filter (Cat. No. YM-30 Membranes Cat. No.         13742, Amicon)     -   Multi-channel Automated Pipettor (Cat. No. 4880, Corning Costar,         Cambridge, Mass.)     -   pH Meter Corning 240 (Corning Science Products, Corning         Glassworks, Corning, N.Y.)     -   ACT396 peptide synthesizer (Advanced ChemTech, Louisville, Ky.)     -   Vacuum dryer (Box from Labconco, Kansas City, Mo. and Pump from         Alcatel, Laurel, Md.).

Lyophilizer (Unitop 600sl in tandem with Freezemobile 12, both from Virtis, Gardiner, N.Y.)

Peptide Selection

Peptide or peptides against which antibodies would be raised were selected from within the protein sequence of interest using a program that uses the Hopp/Woods method (described in Hopp and Woods, Mol. Immunol. 20:483, 1983 and Hopp and Woods, Proc. Nat. Acad. Sci. U.S.A. 78:3824, 1981). The program uses a scanning window that identifies peptide sequences of 15-20 amino acids containing several putative antigenic epitopes as predicted by low solvent accessibility. This is in contrast to most implementations of the Hopp/Woods method, which identify single short (˜6 amino acids) presumptive antigenic epitopes. Occasionally the predicted solvent accessibility was further assessed by PHD prediction of loop structures (described in Rost and Sander, Proteins 20:216, 1994). Preferred peptide sequences display minimal similarity with additional known human proteins. Similarity was determined by performing BLASTP alignments, using a wordsize of 2 (described in Altschul et al., J. Mol. Biol. 215:403, 1990). All alignments given an EXPECT value less than 1000 were examined and alignments with similarities of greater than 60% or more than four residues in an exact contiguous non-gapped alignment forced those peptides to be rejected. When it was desired to target regions of proteins exposed outside the cell membrane, extracellular regions of the protein of interest were determined from the literature or as defined by predicted transmembrane domains using a hidden Markov model (described in Krogh et al., J. Mol. Biol. 305:567, 2001). When the peptide sequence was in an extracellular domain, peptides were rejected if they contained N-linked glycosylation sites. As shown in Appendix A, for the preparation of TLE3 antibodies a single peptide was used having the amino acid sequence KNHHELDHRERESSAN (SEQ ID NO. 383). Appendix A provides one to three peptide sequences that can be used in preparing antibodies against other markers.

Peptide Synthesis

The sequence of the desired peptide was provided to the peptide synthesizer. The C-terminal residue was determined and the appropriate Wang Resin was attached to the reaction vessel. The peptide or peptides were synthesized C-terminus to N-terminus by adding one amino acid at a time using a synthesis cycle. Which amino acid is added was controlled by the peptide synthesizer, which looks to the sequence of the peptide that was entered into its database. The synthesis steps were performed as follows:

Step 1—Resin Swelling: Added 2 ml DMF, incubated 30 minutes, drained DMF.

Step 2—Synthesis cycle (repeated over the length of the peptide)

-   -   2a—Deprotection: 1 ml deprotecting solution was added to the         reaction vessel and incubated for 20 minutes.     -   2b—Wash Cycle     -   2c—Coupling: 750 ml of amino acid solution (changed as the         sequence listed in the peptide synthesizer dictated) and 250 ml         of DIC solution were added to the reaction vessel. The reaction         vessel was incubated for thirty minutes and washed once. The         coupling step was repeated once.     -   2d—Wash Cycle

Step 3—Final Deprotection: Steps 2a and 2b were performed one last time.

Resins were deswelled in methanol (rinsed twice in 5 ml methanol, incubated 5 minutes in 5 ml methanol, rinsed in 5 ml methanol) and then vacuum dried.

Peptide was removed from the resin by incubating 2 hours in reagent R and then precipitated into ether. Peptide was washed in ether and then vacuum dried. Peptide was resolubilized in diH₂O, frozen and lyophilized overnight.

Conjugation of Peptide with Keyhole Limpet Hemocyanin

Peptide (6 mg) was conjugated with Keyhole Limpet Hemocyanin (KLH). If the selected peptide includes at least one cysteine, three aliquots (2 mg) can be dissolved in PBS (2 ml) and coupled to KLH via glutaraldehyde, EDC or maleimide activated KLH (2 mg) in 2 ml of PBS for a total volume of 4 ml. When the peptide lacks cysteine (as in the TLE3 peptide), two aliquots (3 mg) can be coupled via glutaraldehyde and EDC methods.

Maleimide coupling can be accomplished by mixing 2 mg of peptide with 2 mg of maleimide-activated KLH dissolved in PBS (4 ml) and incubating 4 hr.

EDC coupling can be accomplished by mixing 2 mg of peptide, 2 mg unmodified KLH, and 20 mg of EDC in 4 ml PBS (lowered to pH 5 by the addition of phosphoric acid), and incubating for 4 hours. The reaction is then stopped by the slow addition of 1.33 ml acetic acid (pH 4.2). When using EDC to couple 3 mg of peptide, the amounts listed above are increased by a factor of 1.5.

Glutaraldehyde coupling occurs when 2 mg of peptide are mixed with 2 mg of KLH in 0.9 ml of PBS. 0.9 ml of 0.2% glutaraldehyde in PBS is added and mixed for one hour. 0.46 ml of 1 M glycine in PBS is added and mixed for one hour. When using glutaraldehyde to couple 3 mg of peptide, the above amounts are increased by a factor of 1.5.

The conjugated aliquots were subsequently repooled, mixed for two hours, dialyzed in 1 liter PBS and lyophilized.

Immunization of Rabbits

Two New Zealand White Rabbits were injected with 250 μg (total) KLH conjugated peptide in an equal volume of complete Freund's adjuvant and saline in a total volume of 1 ml. 100 μg KLH conjugated peptide in an equal volume of incomplete Freund's Adjuvant and saline were then injected into three to four subcutaneous dorsal sites for a total volume of 1 ml two, six, eight and twelve weeks after the first immunization. The immunization schedule was as follows:

Day 0 Pre-immune bleed, primary immunization Day 15 1st boost Day 27 1st bleed Day 44 2nd boost Day 57 2nd bleed and 3rd boost Day 69 3rd bleed Day 84 4th boost Day 98 4th bleed Collection of Rabbit Serum

The rabbits were bled (30 to 50 ml) from the auricular artery. The blood was allowed to clot at room temperature for 15 minutes and the serum was separated from the clot using an IEC DPR-6000 centrifuge at 5000 g. Cell-free serum was decanted gently into a clean test tube and stored at −20° C. for affinity purification.

Determination of Antibody Titer

All solutions with the exception of wash solution were added by the Hamilton Eclipse, a liquid handling dispenser. The antibody titer was determined in the rabbits using an ELISA assay with peptide on the solid phase. Flexible high binding ELISA plates were passively coated with peptide diluted in BBS (100 μl, 1 μg/well) and the plate was incubated at 4° C. in a wetbox overnight (air-tight container with moistened cotton balls). The plates were emptied and then washed three times with BBS containing 0.1% Tween-20 (BBS-TW) by repeated filling and emptying using a semi-automated plate washer. The plates were blocked by completely filling each well with BBS-TW containing 1% BSA and 0.1% gelatin (BBS-TW-BG) and incubating for 2 hours at room temperature. The plates were emptied and sera of both pre- and post-immune serum were added to wells. The first well contained sera at 1:50 in BBS. The sera were then serially titrated eleven more times across the plate at a ratio of 1:1 for a final (twelfth) dilution of 1:204,800. The plates were incubated overnight at 4° C. The plates were emptied and washed three times as described.

Biotinylated goat anti-rabbit IgG (100 μl) was added to each microtiter plate test well and incubated for four hours at room temperature. The plates were emptied and washed three times. Horseradish peroxidase-conjugated Streptavidin (100 μl diluted 1:10,000 in BBS-TW-BG) was added to each well and incubated for two hours at room temperature. The plates were emptied and washed three times. The ABTS was prepared fresh from stock by combining 10 ml of citrate buffer (0.1 M at pH 4.0), 0.2 ml of the stock solution (15 mg/ml in water) and 10 μl of 30% hydrogen peroxide. The ABTS solution (100 μl) was added to each well and incubated at room temperature. The plates were read at 414 nm, 20 minutes following the addition of substrate.

Preparation of Peptide Affinity Purification Column:

The affinity column was prepared by conjugating 5 mg of peptide to 10 ml of cyanogen bromide-activated Sepharose 4B and 5 mg of peptide to hydrazine-Sepharose 4B. Briefly, 100 μl of DMF was added to peptide (5 mg) and the mixture was vortexed until the contents were completely wetted. Water was then added (900 μl) and the contents were vortexed until the peptide dissolved. Half of the dissolved peptide (500 μl) was added to separate tubes containing 10 ml of cyanogen-bromide activated Sepharose 4B in 0.1 ml of borate buffered saline at pH 8.4 (BBS) and 10 ml of hydrazine-Sepharose 4B in 0.1 M carbonate buffer adjusted to pH 4.5 using excess EDC in citrate buffer pH 6.0. The conjugation reactions were allowed to proceed overnight at room temperature. The conjugated Sepharose was pooled and loaded onto fritted columns, washed with 10 ml of BBS, blocked with 10 ml of 1 M glycine and washed with 10 ml 0.1 M glycine adjusted to pH 2.5 with HCl and re-neutralized in BBS. The column was washed with enough volume for the optical density at 280 nm to reach baseline.

Affinity Purification of Antibodies

The peptide affinity column was attached to a UV monitor and chart recorder. The titered rabbit antiserum was thawed and pooled. The serum was diluted with one volume of BBS and allowed to flow through the columns at 10 ml per minute. The non-peptide immunoglobulins and other proteins were washed from the column with excess BBS until the optical density at 280 nm reached baseline. The columns were disconnected and the affinity purified column was eluted using a stepwise pH gradient from pH 7.0 to 1.0. The elution was monitored at 280 nm and fractions containing antibody (pH 3.0 to 1.0) were collected directly into excess 0.5 M BBS. Excess buffer (0.5 M BBS) in the collection tubes served to neutralize the antibodies collected in the acidic fractions of the pH gradient.

The entire procedure was repeated with “depleted” serum to ensure maximal recovery of antibodies. The eluted material was concentrated using a stirred cell apparatus and a membrane with a molecular weight cutoff of 30 kD. The concentration of the final preparation was determined using an optical density reading at 280 nm. The concentration was determined using the following formula: mg/ml=OD₂₈₀/1.4.

It will be appreciated that in certain embodiments, additional steps may be used to purify antibodies of the invention. In particular, it may prove advantageous to repurify antibodies, e.g., against one of the peptides that was used in generating the antibodies. It is to be understood that the present invention encompasses antibodies that have been prepared with such additional purification or repurification steps. It will also be appreciated that the purification process may affect the binding between samples and the inventive antibodies.

Example 2 Preparing and Staining Tissue Arrays

This example describes a method that was employed to prepare the tissue arrays that were used in the Examples. This example also describes how the antibody staining was performed.

Tissue arrays were prepared by inserting full-thickness cores from a large number of paraffin blocks (donor blocks) that contain fragments of tissue derived from many different patients and/or different tissues or fragments of tissues from a single patient, into a virgin paraffin block (recipient block) in a grid pattern at designated locations in a grid. A standard slide of the paraffin embedded tissue (donor block) was then made which contained a thin section of the specimen amenable to H & E staining. A trained pathologist, or the equivalent versed in evaluating tumor and normal tissue, designated the region of interest for sampling on the tissue array (e.g., a tumor area as opposed to stroma). A commercially available tissue arrayer from Beecher Instruments was then used to remove a core from the donor block which was then inserted into the recipient block at a designated location. The process was repeated until all donor blocks had been inserted into the recipient block. The recipient block was then thin-sectioned to yield 50-300 slides containing cores from all cases inserted into the block.

The selected antibodies were then used to perform immunohistochemical staining using the DAKO Envision+, Peroxidase IHC kit (DAKO Corp., Carpenteria, Calif.) with DAB substrate according to the manufacturer's instructions. FIG. 1 shows exemplary IHC staining images of samples that are TLE3-negative (S0643−) and TLE3-positive (S0643+).

Example 3 TLE3 Expression Correlates with Response to Chemotherapy in Cancer Patients

Tumor samples from two different breast cancer cohorts—Huntsville Hospital (HH) and Roswell Park Cancer Institute (RP)—were stained with the TLE3 antibody of Example 1. Treatment and recurrence data were available for all patients in both cohorts. FIG. 2 shows Kaplan-Meier recurrence curves that were generated using all patients in the HH cohort after classification based on staining with the TLE3 antibody. Recurrence data from TLE3-positive and TLE3-negative patients were used to generate the top and bottom curves, respectively. As shown in the Figure, antibody binding to the TLE3 marker correlates with improved prognosis across this breast cancer cohort (HR=0.573, p=0.004). FIG. 3 shows Kaplan-Meier recurrence curves that were generated in a similar fashion using all patients in the RP cohort. As with the HH cohort, antibody binding to the TLE3 marker was found to correlate with improved prognosis (HR=0.239, p=0.011).

In order to determine whether TLE3 expression is correlated with response to chemotherapy, separate Kaplan-Meier recurrence curves were generated using HH cohort patients that did or did not receive chemotherapy (FIGS. 4 and 5, respectively). As shown in FIG. 4, antibody binding to the TLE3 marker lost its correlation with prognosis in patients that did not receive chemotherapy (HR=0.788, p=0.490). However, as shown in FIG. 5, the correlation was restored in patients that did receive chemotherapy (HR=0.539, p=0.013). These results demonstrate that TLE3 expression is correlated with improved response to chemotherapy (i.e., TLE3-positive cancers are more likely to respond to chemotherapy than TLE-3 negative cancers). Kaplan-Meier recurrence curves that were generated using patients in the RP breast cancer cohort that received chemotherapy are consistent with this prediction model (see FIG. 6, HR=0.194, p=0.010). Kaplan-Meier recurrence curves that were generated using patients in the UAB ovarian cancer cohort that received chemotherapy are also consistent with this prediction model (see FIG. 18, HR=0.64, p=0.049).

Example 4 Specific Chemotherapeutic Correlations

Since different patients in the HH and RP cohorts received different types of chemotherapy we were also able to determine whether TLE3 expression correlates with response to specific types of chemotherapy.

FIG. 7 shows Kaplan-Meier recurrence curves that were generated using patients in the HH breast cancer cohort of FIG. 5 that received CMF (cyclophosphamide, methotrexate and 5-fluorouracil) chemotherapy. Recurrence data from TLE3-positive and TLE3-negative patients in this subset were used to generate the top and bottom curves, respectively. As shown in FIG. 7, antibody binding to the TLE3 marker correlates with improved prognosis across this subset of treated patients (HR=0.398, p=0.019). Based on the results below which demonstrated a loss of correlation for patients in the HH cohort that were treated with CA (cyclophosphamide and adriamycin, HR=1.000) or CAF (cyclophosphamide, adriamycin and 5-fluorouracil, HR=1.000) we were able to establish that the predictive correlation in FIG. 7 is between TLE3 binding and treatment with methotrexate (see also FIG. 9 which combines the CA and CAF treated subsets, HR=1.030).

FIG. 8 shows Kaplan-Meier recurrence curves that were generated using patients in the HH breast cancer cohort of FIG. 5 that received CA or CAF chemotherapy (with or without a taxane). As shown in the Figure, the correlation between antibody binding to the TLE3 marker and prognosis loses significance in this subset of treated patients (HR=0.666, p=0.22). When the curves were generated using patients that received CA or CAF chemotherapy only (i.e., without a taxane) the significance was further reduced (see FIG. 9, HR=1.030, p=0.95). However, the correlation was restored in patients that received CA or CAF in combination with a taxane (see FIG. 10, HR=0.114, p=0.038). These results demonstrate a correlation between TLE3 binding and treatment with a taxane.

FIG. 11 shows Kaplan-Meier recurrence curves that were generated using patients in the RP breast cancer cohort of FIG. 6 that received CA chemotherapy only (i.e., without a taxane). Recurrence data from TLE3-positive and TLE3-negative patients in this subset were used to generate the top and bottom curves, respectively. As shown in the Figure, there is no correlation between antibody binding to the TLE3 marker and prognosis in this subset of treated patients (HR=0.759, p=0.81). The correlation was restored when the curves were generated using patients that received CA chemotherapy in combination with a taxane (see FIG. 12, HR=0.153, p=0.018). These results support the results of FIGS. 8 and 9 that were obtained using samples from the HH cohort.

FIG. 13 shows Kaplan-Meier recurrence curves that were generated using patients in the RP breast cancer cohort of FIG. 6 that received a taxane or CMF. Some of the patients receiving a taxane also received CA. Recurrence data from TLE3-positive and TLE3-negative patients in this subset were used to generate the top and bottom curves, respectively. As shown in the Figure, antibody binding to the TLE3 marker correlates with improved prognosis across this subset of treated patients (HR=0.137, p=0.011).

FIG. 14 shows Kaplan-Meier recurrence curves that were generated using patients in the RP breast cancer cohort of FIG. 6 that received neoadjuvant chemotherapy. Recurrence data from TLE3-positive and TLE3-negative patients in this subset were used to generate the top and bottom curves, respectively. The sample size was small (N=12); however, as shown in the Figure, antibody binding to the TLE3 marker showed significant correlation with improved prognosis across this subset of treated patients when measured using the Fisher Exact Test (p=0.005). In addition, of the 12 patients receiving neoadjuvant chemotherapy, two received CA (both showed recurrence) while ten received CA with a taxane (seven showed recurrence, three did not). Notably, the three patients that did not show any recurrence were the only patients with TLE3-positive samples. These results are significant since they show that the correlation between TLE3 binding and response to chemotherapy applies irrespective of whether treatment is administered in an adjuvant or neoadjuvant setting.

FIGS. 15-17 show Kaplan-Meier recurrence curves that were generated using patients in the RP breast cancer cohort of FIG. 6 that received chemotherapy. Recurrence data from TLE3-positive and TLE3-negative patients with stage II+ (FIG. 15), stage IIb+ (FIG. 16) and stage III+ (FIG. 17) cancers were used to generate the top and bottom curves, respectively. In each case, antibody binding to the TLE3 marker correlated with improved prognosis across these subsets of treated patients. The sample size was small in the subset of FIG. 17 (N=19); however significance was obtained when measured using the Fisher Exact Test (p=0.020). These results are of clinical importance since they demonstrate that the predictive power of the TLE3 marker is independent of stage and remains significant even in patients with the worst prognosis (e.g., stage III+ patients).

Example 5 Bivariate Analysis

In order to confirm that the predictive power of TLE3 is independent of other clinical factors (e.g., age, tumor size, nodes status, necrosis, etc.) we performed bivariate statistical analysis using results from the RP breast cohort. The results are summarized in Table 1 below. As shown in the Table, prediction using TLE3 remained significant in all bivariate analyses demonstrating its independence of other clinical factors.

TABLE 1 Bivariate Analysis Factor Factor HR for p for 1 2 N TLE3 TLE3 HR p TLE3 — 81 0.239 0.0110 — — TLE3 Age 81 0.223 0.0082 0.967 0.1200 TLE3 Tumor Size 78 0.219 0.0077 1.292 0.0002 TLE3 Nodes Met Ca¹ 79 0.252 0.0150 1.066 0.0086 TLE3 Necrosis 72 0.232 0.0100 1.903 0.2600 TLE3 Vasc. Lymph Inv.² 74 0.205 0.0071 0.412 0.0790 TLE3 Stage 80 0.284 0.0280 2.063 0.0130 TLE3 Contains Tax³ 70 0.168 0.0061 2.749 0.0980 ¹Nodes found with metastatic cancer. ²Vascular lymphatic invasion. ³Taxane containing regimens.

Other Embodiments

Other embodiments of the invention will be apparent to those skilled in the art from a consideration of the specification or practice of the invention disclosed herein. It is intended that the specification and examples be considered as exemplary only, with the true scope of the invention being indicated by the following claims.

APPENDIX A PEPTIDE 1 PEPTIDE 2 PEPTIDE 3 ENTREZ (SEQ ID (SEQ ID (SEQ ID AGI ID GENE NAME GENE ID ALIASES NO.) NO.) NO.) TITER S0011 vav 3 oncogene 10451 VAV3; VAV3 ONCOGENE; TEESINDEDIY EKRTNGLRR DYISKSKEDV 1:90- ONCOGENE VAV3; vav 3 KGLPDLIDE TPKQVD KLK 1:300 oncogene (1) (2) (3) S0017 WAP four- 10406 WFDC2; WAP5; dJ461P17.6; EKTGVCPELQ PNDKEGSCP RDQCQVDTQ 1:25- disulfide major epididymis-specific ADQNCTQE QVNIN (5) CPGQMK (6) 1:500 core domain 2 protein E4; epididymal (4) secretory protein E4; WAP four-disulfide core domain 2; WAP domain containing protein HE4-V4; epididymis-specific, whey- acidic protein type, four- disulfide core; WAP four- disulfide S0018 secretoglobin, 4250 UGB2; MGB1; SCGB2A2; SKTINPQVSKT DDNATTNAID NQTDETLSNV 1:300- family 2A, mammaglobin 1; secreto- EYKELLQE ELKEC (8) EVFMQ (9) 1:1000 member 2 globin, family 2A, (7) member 2 S0020 PPAR binding 5469 RB18A; TRIP2; PPARGBP; SSDDGIRPLPE DGKSKDKPP NKTKKKKSSR 1:100 protein PBP; CRSP1; PPARBP; YSTEKHKK KRKKADTE LPPEK (12) CRSP200; DRIP230; PPAR- (10) (11) BINDING PROTEIN; PPARG binding protein; PPAR binding protein; CRSP, 200 KD SUBUNIT; PEROXISOME PROLIFERATOR- ACTIVATED RECEPTOR- BINDING PROTEIN; THYROID HORMONE RECEPTOR INTERACTOR 2; RECOGN S0021 hypothetical 222256 FLJ23834; hypothetical KNKEPLTKKG KLTCTDLDSS EVDYENPSNL 1:200- protein protein FLJ23834 ETKTAERD PRSFRYS AAGNKYT 1:2500 FLJ23834 (13) (14) (15) S0022 cytochrome 199974 CYP4Z1; cytochrome P450 KTLQVFNPLR QHFAIIECKV RKFLAPDHSR 1:50- P450 4Z1 4Z1; cytochrome P450, FSRENSEKIH AVALT (17) PPQPVRQ 1:500 family 4, subfamily Z, (16) (18) polypeptide 1 S0024 RAS-like, 85004 RERG; RAS-like, estrogen- MAKSAEVKLAI VLPLKNILDEI YELCREVRR 1:900- estrogen- regulated, growth- FGRAGVGK KKPKN (20) RRMVQGKT 1:2700 regulated inhibitor (19) (21) growth- inhibitor S0032 fatty acid 2170 MDGI; O-FABP: FABP3; TKPTTIIEKNG KNTEISFKLG HLQKWDGQE 1:225 binding FABP11; H-FABP; FATTY DILTLKTH VEFDE (23) TTLVRE (24) protein 3, ACID-BINDING PROTEIN, (22) muscle and SKELETAL MUSCLE; Fatty heart acid-binding protein 3, (mammary- muscle; fatty acid derived binding protein 11; FATTY growth ACID-BINDING PROTEIN, inhibitor) MUSCLE AND HEART; fatty acid binding protein 3, muscle and heart (mammary-de S0036 gamma- 2568 GABRP; GAMMA-AMINOBUTYRIC DGNDVEFTWL LQQMAAKDR KRKISFASIEI 1:250- aminobutyric ACID RECEPTOR; PI; GABA-A RGNDSVRGLE GTTKEVEEV SSDNVDYSD 1:500 acid (GABA) RECEPTOR, PI POLYPEPTIDE; H (25) S (26) (27) A receptor, gamma-aminobutyric acid pi (GABA) A receptor, pi S0037 annexin AB 244 ANX8; ANXA8; annexin VIII; QRQQIAKSFK REIMKAYEED EEYEKIANKSI 1:30-1:40 annexin A8 AQFGKDLTE YGSSLEEDIQ EDSIKSE (28) (29) (30) S0039 CDNA FLJ25076 134111 similar to 3110006E14Rik EGGSLVPAAR RKAGKSKKS KTHEKYGWV 1:50- fis, clone protein; CDNA FLJ25076 QQHCTQVRS FSRKEAE TPPVSDG 1:30000 CBL06117 fis, done CBL06117 RR (31) (32) (33) S0040 ATP-binding 5243 P-gp; PGY1; CLCS; ABCB1; MDLEGDRNG NLEDLMSNIT RGSQAQDRK 1:200- cassette, ABC20; CD243; GP170; GAKKKN (34) NRSDINDTG LSTKEA (36) 1:400 sub-family B MDR1; doxorubicin resis- (35) (MDR/TAP), tance; colchicin member 1 sensitivity; P-GLYCOPRO- TEIN 1; multidrug resis- tance 1; P glycoprotein 1; ATP-binding cassette sub-family B member 1; ATP-BINDING CASSETTE, SUBFAMILY B, MEMBER 1; ATP-bin S0041 ATP-binding 5244 MDR3; PGY3; PFIC-3; MDLEAAKNGT NFSFPVNFSL KNSQMCQKS 1:60- cassette, sub- ABCB4; ABC21; MDR2/3; AWRPTSAE SLLNPGK LDVETDG 1:300 family B P-GLYCOPROTEIN 3; (37) (38) (39) (MDR/TAP), MULTIDRUG RESISTANCE 3; member 4 P-glycoprotein-3/multiple drug resistance-3; P glycoprotein 3/multiple drug resistance 3; ATP- binding cassette, sub- family B (MDR/TAP), member 4; ATP-binding cassette, sub S0042 ATP-binding 4363 ABCC1; MRP1; GS-X; ABC29; MALRGFCSAD KNWKKECAK DSIERRPVKD 1:40- cassette, multidrug resistance GSD (40) TRKQPVK GGGTNS (42) 1:500 sub-family C protein; MULTIDRUG RESIS- (41) (CFTR/MRP), TANCE-ASSOCIATED PROTEIN member 1 1; multiple drug resistance-associated protein; multiple drug resistance protein 1; ATP-BINDING CASSETTE, SUBFAMILY C, MEMBER 1; ATP-binding cassette, sub-fami S0043 ATP-binding 1244 MRP2; cMRP; CMOAT; ABCC2; MLEKFCNSTF SILCGTQFQ ENNESSNNP 1:50- cassette, ABC30; DJS; MULTIDRUG WNSSFLDSPE TLIRT (44) SSIAS (45) 1:333 sub-family C RESISTANCE-ASSOCIATED (43) (CFTR/MRP), PROTEIN 2; canalicular member 2 multispecific organic anion transporter; MULTI- SPECIFIC ORGANIC ANION TRANSPORTER, CANALICULAR; ATP-BINDING CASSETTE, SUBFAMILY C, MEMBER 2; ATP-binding cassette, S0044 ATP-binding 10257 MOAT-B; MRP4; MOATB; QEVKPNPLQD DEISQRNRQ VQDFTAFWD 1:20- cassette, ABCC4; EST170205; MULTI- ANICSR (46) LPSDGKK KASETPTLQ 1:100 sub-family C DRUG RESISTANCE- (47) (48) (CFTR/MRP), ASSOCIATED PROTEIN 4; member 4 MULTISPECIFIC ORGANIC ANION TRANSPORTER B; ATP-binding cassette, sub-family C, member 4; ATP-BINDING CASSETTE, SUBFAMILY C, MEMBER 4; ATP-binding cassette, sub-family C (CFT S0045 ATP-binding 8714 MOAT-D; ABC31; MLP2; MDALCGSGEL RKQEKQTAR DPQSVERKTI 1:2000 cassette, ABCC3; EST90757; cMOAT2; GSKFWDSN HKASAA (50) SPG (51) sub-family C MULTIDRUG RESISTANCE- (49) (CFTR/MRP), ASSOCIATED PROTEIN 3; member 3 canicular multispecific organic anion transporter; CANALICULAR MULTISPECIFIC ORGANIC ANION TRANSPORTER 2; ATP- BINDING CASSETTE, SUB- FAMILY C. MEMBER 3; ATP- binding cas S0046 ATP-binding 10057 MOAT-C; ABCC5; MRP5; MKDIDIGKEYI RDREDSKFR SKHESSDVN 1:100- cassette, EST277145; ABC33; SMRP; IPSPGYRS RTRPLECQD CRRLER (54) 1:4500 sub-family C pABC11; MOATC; MULTIDRUG (52) (53) (CFTR/MRP), RESISTANCE-ASSOCIATED member 5 PROTEIN 5; canalicular multispecific organic anion transporter C; ATP-binding cassette, sub-family C, member 5; ATP-BINDING CASSETTE, SUBFAMILY C, MEMBER 5; ATP-bi S0047 ATP-binding 368 MRP6; ARA; EST349056; MAAPAEPCAG DRGVVDSSS HTLVAENAM 1:50 cassette, ABCC6; MOATE; PXE; MLP1; QGVWNQTEP SGSAAGKD NAEK (57) sub-family C ABC34; ANTHRACYCLINE; E (55) (56) (CFTR/MRP), RESISTANCE-ASSOCIATED member 6 PROTEIN; MULTIDRUG RESISTANCE-ASSOCIATED PROTEIN 6; ATP-binding cassette, sub-family C, member 6; ATP-BINDING CASSETTE, SUBFAMILY C, MEMBER 6; ATP-binding cassette, S0048 ATP-binding 8647 BSEP; ABCB11; PFIC-2; MSDSVILRSIK TNSSLNQNM QEVLSKIQHG 1:600 cassette SPGP; PGY4; PFIC2; ABC16; KFGEEND TNGTR (59) HTIIS (60) sub-family B SISTER OF P-GLYCOPROTEIN (58) (MDR/TAP), bile salt export pump; member 11 progressive familial intrahepatic cholestasis 2; ABC member 16, MDR/TAP subfamily; ATP-BINDING CASSETTE, SUBFAMILY B, MEMBER 11; ATP-binding cassette, sub-fam S0049 ATP-binding 23456 MTABC2; EST20237; MABC2; GADDPSSVTA NAVASPEFP KPNGIYRKLM 1:10-1:25 cassette, M-ABC2; ABCB10; MITO- EEIQR (61) PRFNT (62) NKQSFISA sub-family B CHONDRIAL ABC PROTEIN 2; (63) (MDR/TAP), ATP-BINDING CASSETTE, member 10 SUBFAMILY B, MEMBER 10; ATP-binding cassette, sub-family B, member 10; ATP-binding cassette, sub-family B (MDR/TAP), member 10 S0050 transporter 1, 6890 RING4; ABC17; D6S114E; MASSRCPAPR QGGSGNPVR EFVGDGIYNN 1:80 ATP-binding ABCB2; TAP1; APT1; GCR (64) R (65) TMGHVHS cassette, PEPTIDE TRANSPORTER PSF1; (66) sub-family B TRANSPORTER, ABC, MHC, 1; (MDR/TAP) ABC transporter, MHC 1; antigen peptide transporter 1; peptide supply factor 1; ABC TRANSPORTER, MHC, 1; ATP- BINDING CASSETTE, SUBFAMILY B, MEMBER 2; TRANSPORTER S0052 ATP-binding 6833 SUR1; MRP8; PHHI; ABC36; MPLAFCGSEN DHLGKENDV EIREEQCAPH 1:25- cassette, ABCC8; HRINS; sulfonylurea HSAAYR FQPKTQFLG EPTPQG 1:150 sub-family C receptor (hyperinsuli- (67) (68) (69) (CFTR/MRP), nemia); SULFONYLUREA member 8 RECEPTOR, BETA-CELL HIGH- AFFINITY; ATP-binding cassette, sub-family C, member 8; ATP-BINDING CASSETTE, SUBFAMILY C, MEMBER 8; ATP-binding cassette, sub-family C S0053 ATP-binding 10060 ABCC9; ABC37; sulfony- MSLSFCGNNI QRVNETQNG DEIGDDSWR 1:25-1:50 cassette, lurea receptor 2A; ATP- SS (70) TNNTTGISE TGESSLPFE sub-family C BINDING CASSETTE, (71) (72) (CFTR/MRP), SUBFAMILY C, MEMBER 9; member 9 ATP-binding cassette, sub- family C (CFTR/MRP), member 9; ATP-binding cassette, sub-famly C, member 9 isoform SUR2B; ATP-binding cassette, sub- family C, member 9 isoform S0055 integral mem- 9445 E25B; ABRI; E3-16; FBD; MVKVTFNSAL QTIEENIKIFE HDKETYKLQ 1:450- brane protein BRI2; BRICD2B; ITM2B; BRI AQKEAKKDEP EEEVE (74) RRETIKGIQK 1:500 2B GENE; BRICHOS domain con- K (73) RE (75) taining 2B; integral membrane protein 2B S0057 ankyrin 3, 288 ankyrin-G; ANK3; ankyrin- MAHAASQLKK HKKETESDQ EGFKVKTKKE 1:750 node of 3, node of Ranvier; NRDLEINAEE DDEIEKTDRR IRHVEKKSHS Ranvier ankyrin 3 isoform 1; (76) Q (77) (78) (ankyrin G) ankyrin 3 isoform 2; ankyrin 3, node of Ranvier (ankyrin G) S0058 hypothetical 80004 FLJ21918; hypothetical ERALAAAQRC TAGMKDLLS DPPRTVLQAP 1:20 protein protein FLJ21918 HKKVMKER VFQAYQ (80) KEWVCL (81) FLJ21918 (79) S0059 tripartite 23650 ATDC; TRIM29; tripartite MEAADASRSN ELHLKPHLEG EGEGLGQSL 1:50- motif- motif-containing 29; GSSPEARDAR AAFRDHQ GNFKDDLLN 1:3000 containing 29 ataxia-telangiectasia (82) (83) (84) group D-assocaited protein; tripartite motif protein TRIM29 isoform alpha; tripartite motif protein TRIM29 isoform beta S0059P2 tripartite 23650 ATDC; TRIM29; tripartite ELHLKPHLEG N/A N/A 1:30-1:90 motif- motif-containing 29; AAFRDHQ containing 29 ataxia-telangiectasia (85) group D-associated protein; tripartite motif protein TRIM29 isoform alpha; tripartite motif protein TRIM29 isoform beta S0063 iroquois 79191 IRX3; iroquois homeobox GSEERGAGR KIWSLAETAT KKLLKTAFQP 1:200- homeobox protein 3 GSSGGREE SPDNPRRS VPRRPQNHL 1:1200 protein 3 (86) (87) D (88) S0068 RAS-like, 85004 RERG; RAS-like, estrogen- RRSSTTHVKQ N/A N/A 1:500- estrogen- regulated, growth- AINKMLTKIS 1:40000 regulated, inhibitor S (89) growth- inhibitor S0070 G protein- 26996 GPCR150; GPR160; putative MRRKNTCQNF NETILYYFPFS KVQIPAYIEM 1:10- coupled G protein-coupled MEYFCISLAF SHSSYTVRS NIPLVILCQ 1:100 receptor 160 receptor; G protein- (90) KK (91) (92) coupled receptor 160 S0072 S100 calcium 6279 CP-10; L1Ag; CALPROTECTIN; MLTELEKALN RDDKKLLET KMGVAAHKK 1:6500- binding 60B8AG; S100A8; MIF; CAGA; SIIDVYTHK ECPQYIRKKG SHEESHKE 1:10000 protein A8 NIF; MRP8; MA387; (93) AD (94) (95) (calgranulin CFAG; CGLA S100A8/ A) S100A9 COMPLEX; cystic fibrosis antigen; S100 calcium-binding protein A8; S100 calcium binding protien A8 (calgranlin A) S0073 forkhead box 3169 HNF3A; MGC33105; TCF3A; PESRKDPSGA HGLAPHESQ EQQHKLDFK 1:100- A1 FOXA1; forkhead box A1; SNPSADS LHLKGD (97) AYEQALQYS 1:2700 HEPATOCYTE NUCLEAR FACTOR (96) (98) 3-ALPHA; hepatocyte nuclear factor 3, alpha S0073P2 forkhead box 3169 HNF3A; MGC33105; TCF3A; HGLAPHESQL N/A N/A 1:50- A1 FOXA1; forkhead box A1; HLKGD 1:450 HEPATOCYTE NUCLEAR FACTOR (99) 3-ALPHA; hepatocyte nuclear factor 3, alpha S0074 trefoil factor 7033 TFF3; trefoil factor 3, EEYVGLSANQ RVDCGYPHV VPWCFKPLQ 1:2500- 3 (intestinal) (intestinal); trefoil CAVPAKDRVD TPKECN EAECTF 1:30000 factor 3, HITF, human (100) (101) (102) intestinal trefoil factor S0074P3 trefoil factor 7033 TFF3; trefoil factor 3, VPWCFKPLQE N/A N/A 1:400- 3 (intestinal) (intestinal); trefoil AECTF (103) 1:810 factor 3, HITF, human intestinal trefoil factor S0076x1 keratin 17 3872 PC2; PCHC1; KRT17; K17; KKEPVTTRQV QDGKVISSR SSSIKGSSGL 1:200 CYTOKERATIN 17; keratin 17 RTIVEE EQVHQTTR GGGSS (106) (104) (105) S0078 kynureninase 8942 3.71.3; XANTHURENICACI- DEEDKLRHFR KPREGEETL EERGCQLTIT 1:180- (L-kynurenine DURIA; KYNU; HYDROXYKYNUR- ECFIPKIQD RIEDILEVIEK FSVPNKDVF 1:200 hydrolase) ENINURIA; KYNURENINASE (107) E (108) QE (109) DEFICIENCY; XANTHURENIC ACIDURIA; kynureninase (L-kynurenine hydrolase) S0079 solute 25800 SLC39A6; LIV-1 protein, DHNHAASGKN EEPAMEMKR QRYSREELK 1:200- carrier estrogen relulated; solute KRKALCPDHD GPLFSHLSS DAGVATL 1:800 family 39 carrier family 39 (zinc (110) QNI (111) (112) (zinc transporter), member 6; transporter), solute carrier family 39 member 6 (metal ion transporter), member 6 S0081 N-acetyl- 9 AAC1; 2.3.1.5; NAT1; MDIEAYLERIG QMWQPLELI FNISLQRKLV 1:10- transferase 1 arylamine N-acetyltrans- YKKSRNKLDL SGKDQPQVP PKHGDRFFTI 1:240 (arylamine N- ferase-1; ACETYL-CoA: E (113) CVFR (114) (115) acetyltrans- ARYLAMINE N-ACETYLTRANS- ferase) FERASE; ARYLAMINE N- ACETYLTRANSFERASE 1; N-acetyltransgerase 1 (arylamine N-acetyltrans- ferase); arylamide acetylase 1 (N-acetyl- transferase 1) S0086 X-box binding 7494 XBP2; TREB5; XBP1; X-box- RQRLTHLSPE EKTHGLVVE QPPFLCQWG 1:180- protein 1 binding protein-1; X BOX- EKALRRKLKN NQELRQRLG RHQPSWKPL 1:400 BINDING PROTEIN 1; X BOX- R (116) MD (117) MN (118) BINDING PROTEIN 2; X-box binding protein 1 S0088 claudin 10 9071 CPETRL3; OSP-L; CLDN10; NKITTEFFDPL FSISDNNKTP EDFKTTNPSK 1:333- claudin 10; claudin 10 FVEQK (119) RYTYNGAT QFDKNAYV 1:1000 isoform a; claudin 10 (120) (121) isoform b S0090 sparc/ 9806 KIAA0275; testican-2; EGDAKGLKEG EWCFCFWR EEEGEAGEA 1:100- osteonectin, SPOCK2; TESTICAN 2; SPARC/ ETPGNFMEDE EKPPCLAELE DDGGYIW 1:800 cwcv and OSTEONECTIN, CWCV, AND (122) R (123) (124) kazal-like KAZAL-LIKE DOMAINS domains pro- PROTEOGLYCAN 2; sparc/ teoglycan osteonectin, cwcv and (testican) 2 kazal-like domains proteoglycan (testican) 2 S0091 lipocalin 2 3934 UTEROCALIN; NGAL; LCN2; DKDPQKMYAT KKCDYWIRT ENFIRFSKYL 1:100 (oncogene NEUTROPHIL GELATINASE- IYE (125) FVPGCQ GLPEN (127) 24p3) ASSOCIATED LIPOCALIN; (126) ONOGENIC LIPOCALIN 24P3; lipocalin 2 (oncogene 24p3) S0092 paired box 7849 PAX8; paired box gene 8; DDSDQDSCRL RQHYPEAYA NTPLGRNLST 1:30- gene 8 paired box gene 8 isoform SIDSQ (128) SPSHTK HQTYPVVAD 1:100 PAX8C; paired box gene 8 (129) (130) isoform PAX8D; paired box gene 8 isoform PAX8E; paired box gene 8 isoform PAX8A; paired box gene 8 isoform PAX8B; PAIRED DOMAIN GENE 8 PAX8/ PPARG FUSION GENE S0093 mesothelin 10232 CAK1; SMR; MSLN; RLVSCPGPLD KMSPEDIRK SPEELSSVPP 1:500 mesothelin; MEGAKARYOCYTE- QDQQE (131) WNVTSLETL SSIWAVRPQ POTENTIATING FACTOR; K (132) D (133) SOLUBLE MPF/MESOTHELIN- RELATED PROTEIN; mesothelin isoform 2 precursor; mesothelin isoform 1 precursor, megakaryocyte potentiating factor precursor; ANTIGEN RECOGNIZED BY MONOCLONAL ANTIBODY S0094 kallikrein 6 5653 Bssp; PRSS18; KLK6; Klk7; EEQNKLVHGG ELIQPLPLER GKTADGDFP 1:150- (neurosin, SP59; PRSS9; MGC9355; PCDKTSH DCSANT DTIQC (136) 1:300 zyme) protease M; kallikrein 6 (134) (135) preproprotein; protease, serine, 18; protease, serine, 9; kallikrein 6 (neurosin, zyme) S0095 Rap guanine 10411 bcm910; MGC21410; REQWPERRR KVNSAGDAI QQLKVIDNQR 1:250- nucleotide 93301705Rik; EPAC; CHRLENGCGN GLQPDAR ELSRLSRELE 1:1000 exchange RAPGEF3; cAMP-GEFI; RAP A (137) (139) (140) factor (GEF) 3 guanine-nucleotide- exchange factor 3; EXCHANGE PROTEIN ACTIVATED BY cAMP; RAP guanine- nucleotide-exchange factor (GEF) 3; cAMP-REGULATED GUANINE NUCLEOTIDE EXCHANGE FACTOR I; RAP GUANINE NUCLE S0096 ATPase, H+ 525 Vma2; VPP3; ATP6V1B1; REHMQAVTRN KKSKAVLDY DEFYSREGR 1:100- transporting, RTA1B; 3.63.14; VATB; YITHPR HDDN (142) LQDLAPDTAL 1:800 lysosomal 56/ ATP6B1; V-ATPase B1 (141) (143) 58 kDa, V1 subunit; H+-ATPase subunit B, beta 1 subunit; H(+)- isoform 1 transporting two-sector (Renal tubular ATPase, 58 kD subunit; acidosis with vacuolar proton pump, deafness) subunit 3; endomembrane proton pump 58 kDa subunit; ATPase, H+ transporting, lysos S0097 frizzled 8325 FZ-8; hFZ8; FZD8; frizzled KQQDGPTKTH ELRVLSKANA RRGGEGGEE 1:100- homolog 8 8; frizzled homolog 8 KLEKLMIR IVPGLSGGE NPSAAKGHL 1:500 (Drosophila) (Drosophila; FRIZZLED, (144) (145) MG (146) DROSOPHILA, HOMOLOG OF, 8 S0099 histone 1, 255626 HIST1H2BA; histone 1, H2ba MPEVSSKGAT GFKKAVVKT KEGKKRKRT 1:333- H2ba ISKK (147) QK (148) RKE (149) 1:500 S0110 hypothetical 84259 MGC2714; hypothetical RYAFDFARDK SVFYQYLEQ EDGAWPVLL 1:500- protein protein MGC2714 DQRSLDID SKYRVMNKD DEFVEWQKV 1:2500 MGC2714 (150) Q (151) RQTS (152) S0117 reproduction 8 7993 D8S2298E; REP8; repro- SFKSPQVYLK RKKQQEAQG EDIGITVDTVL 1:200- duction 8; Reproduction/ EEEEKNEKR EKASRYIE ILEEKEQTN 1:375 chromoshome 8 (153) (154) (155) S0119 slit homolog 1 6585 SLIT3; MEGF4; SLIL 1; KAFRGATDLK DFRCEEGQE DGTSFAEEVE 1:900 (Drosophila) Slit-1; SLIT1; slit NLRLDKNQ EGGCLPRPQ KPTKCGCAL homolog 1 (Drosophila); (156) (157) CA (158) SLIT, DROSOPHILA, HOMOLOG OF 1; MULTIPLE EPIDERMAL GROWTH FACTOR-LIKE DOMAINS 4 S0122 leucyl-tRNA 23395 6.1.1.4; MGC26121; QRIKEQASKIS HAKTKEKLEV KSPQPQLLSN 1:150 synthetase 2 KIAA0028; LEURS; LARS2; EADKSKPKF TWEKMSKSK KEKAEARK mitochondrial leucine trnslase; leucine- (159) HN (160) (161) tRNA ligase; LEUCYL-tRNA SYNTHETASE, MITOCHONDRIAL; leucyl-tRNA synthetase 2, mitochondrial; leucyl-tRNA synthetase 2, mitochondrial precursor S0123 homeo box D4 3233 HOX4B; HOXD4; HHO.C13; MLFEQGQQAL KDQKAKGILH HSSQGRLPE 1:100- HOX-5.1; HOMEOBOX D4; ELPECT SPASQSPER APKLTHL 1:500 HOMEOBOX 4B; HOMEOBOX X; (162) S (163) (164) homeo box D4; homeobox protein Hox-D4; Hox-4.2, mouse, homolog of homeo box X S0124 sphingosine-1 8879 KIAA1252; SPL; SGPL1; KRGARRGGW KIVRVPLTKM QFLKDIRESV 1:990- phosphate sphingosine-1-phosphate KRKMPSTDL MEVDR TQIMKNPKA 1:1500 lyase 1 lyase 1 (165) (166) (167) S0126 HBxAg trans- 55789 XTP1; HBxAg transactivated SKQGVVILDD VQTFSRCILC LKKPFQPFQR 1:450- activated protein 1 KSKELPHW SKDEVDLDEL TRSFRM 1:1600 protein 1 (168) (169) (170) S0132 SRY (sex 6662 SRA1; CMD1; SOX9; SRY-BOX MNLLDPFMKM NTFPKGEPD KNGQAEAEE 1:100- determining 9; transcription factor TDEQEKGLS LKKESEEDK ATEQTHISPN 1:500 region Y)-box SOX9; SRY-RELATED HMG-BOX (171) (172) (173) 9 (campomelic GENE 9; SEX REVERSAL, dysplasia, AUTOSOMAL, 1; SRY (sex- autosomal sex- determining region Y)-box reversal) 9 protein; SRY (sex- determining region Y)-box 9 (campomelic dysplasia, autosomal sex-reversal); SRY( S0137 cadherin, EGF 1952 Flamingo1; CELSR2; EGFL2; QASSLRLEPG ELKGFAERL RSGKSQPSYI 1:1800- LAG seven-pass KIAA0279; MEGF3; CDHF 10; RANDGWH QRNESGLDS PFLLREE 1:5000 G-type EGF-like-domain, multiple (174) GR (175) (176) receptor 2 2; epidermal growth (flamingo factor-like 2; multiple homolog, epidermal growth factor- Drosophila) like domains 3; cadherin EGF LAG seven-pass G-type receptor 2; cadherin, EGF LAG seven-pass G-type receptor 2 S0139 gamma- 8836 3.4.19.9; GGH; gamma- RRSDYAKVAKI KNFTMNEKL EFFVNEARKN 1:12500- glutamyl glutamyl hydrolase FYNLSIQSFDD KKFFNVLTTN NHHFKSESE 1:30000 hydrolase precursor; gamma-glutamyl (177) (178) E (179) conjugase, hydrolase (conjugase, folypolygamma- folypolygammaglutamyl glutamyl hydrolase) hydrolase) S0140 bullous 667 BP240; FLJ13425; FLJ32235; KNTQAAEALV QENQPENSK KQMEKDLAF 1:250- pemphigoid FLJ21489; FLJ30627; CATX- KLYETKLCE TLATQLNQ QKQVARKQL 1:20000 antigen 1, 15; KIAA0728; BPAG1; (180) (181) K (182) 230/240 kDa dystonin; hemidesmosomal plaque protein; bullous pemphigoid antigen 1, 230/ 240 kDa; bullous pemphigoid antigen 1 (230/240 kD); bullous pemphigoid antigen 1 isoform 1eA precursor; bullo S0143 fatty acid 2194 2.3.1.85; OA-519; FASN; EFVEQLRKEG DRHPQALEA REVRQLTLRK 1:5000- synthase MGC14367; MGC15706; fatty VFAKEVR AQAELQQHD LQELSSKADE 1:30000 acid synthase (183) (184) (185) S0143P3 fatty acid 2194 2.3.1.85; OA-519; FASN; REVRQLTRK N/A N/A 1:200- synthase MGC14367; MGC15706; fatty LQELSSKADE 1:630 acid synthase (186) S0144 matrix 4323 MMP-X1; 3.4.24-; MMP14; AYIREGHEKQ DEASLEPGY RGSFMGSDE 1:500- metallopro- MTMMP1; MT1-MMP; membrane- ADIMFFAE PKHIKELGR VFTYFYK 1:20000 teinase 14 type-1 matrix metallopro- (187) (188) (189) (membrane- teinase 14 preproprotein; inserted) MATRIX METALLOPROTEINASE 14, MEMBRANE-TYPE; matrix metalloproteinase 14 (membrane-inserted); membrane-type matrix metalloprotein S0147 cystatin A 1475 STF1; CSTA; STFA; cystatin MIPGGLSEAK NETYGKLEA DLVLTGYQVD 1:100- (stefin A) AS; cystatin A (stefin A) PATPEIQEIV VQYKTQ KNKDDELTGF 1:50000 (190) (191) (192) S0149 transient 55503 TRPV6; ECAC2: CAT1; CATL; RQEHCMSEHF QGHKWGES RACGKRVSE 1:400- receptor CALCIUM TRANSPORTER 1; KNRPACLGAR PSQGTQAGA GDRNGSGGG 1:20000 potential CALCIUM TRANSPORTER-LIKE (193) GK (194) KWG (195) cation PROTEIN; EPITHELIAL channel, sub- CALCIUM CHANNEL 2; family V, transient receptor member 6 potential cation channel, subfamily V, member 6 S0156 fatty acid 2173 B-FABP; FABP7; FABPB; MRG; MVEAFCATWK QVGNVTKPT KVVIRTLSTFK 1:100- binding mammary-derived growth LTNSQN VIISQE NTE (198) 1:20000 protein 7, inhibitor-related; FATTY (196) (197) brain ACID-BINDING PROTEIN 7; FATTY ACID-BINDING PROTEIN, BRAIN; fatty acid binding protein 7, brain S0158 cadherin 3, 1001 CDHP; HJMD; PCAD; CDH3; RAVFREAEVT QEPALFSTD QKYEAHVPE 1:150- type 1, P- placental cadherin; LEAGGAEQE NDDFTVRN NAVGHE 1:2000 cadherin CADHERIN, PLACENTAL; (199) (200) (201) (placental) cadherin 3, P-cadherin (placental); calcium- dependent adhesion protein, placental; cadhedrin 3, type 1 preproprotein; cadherin 3, type 1, P-cadherin (placental) S0165 chemokine (C- 2919 MGSA-a; NAP-3; CXCL1; KKIIEKMLNSD N/A N/A 1:100- X-C motif) SCYB1; GROa; GRO1, KSN (202) 1:500 ligand 1 FORMERLY; GRO PROTEIN, (melanoma ALPHA; GRO 1 ONCOGENE, growth FORMERLY; MELANOMA GROWTH stimulaing STIMULATORY ACTIVITY, activity, ALPHA; GRO 1 oncogene alpha) (melanoma growth- stimulating activity); CHEMOKINE, CXC MOTIF, LIGAND 1; GRO1 oncogene (melanoma grow S0171 baculoviral null BIRC5; baculoviral IAP GKPGNQNSK QAEAPLVPLS NCFLTERKAQ 1:22500- IAP repeat- repeat-containing 5 NEPPKKRERE RQNK (204) PDE (205) 1:30000 containing 5 (survivin) R (203) (survivin) S0193 procollagen- 5352 PLOD2; LYSYL HYDROXYLASE EFDTVDLSAV NKEVYHEKDI KQVDLENVW 1:20000 lysine, 2- 2; LYSINE HYDROXYLASE 2; DVHPN (206) KVFFDKAK LDFIRE oxoglutarate PROCOLLAGEN-LYSINE, 2- (207) (208) 5-dioxygenase OXOGLUTARATE 5-DIOXY- (lysine GENASE 2; procollagen- hydroxylase) 2 lysine, 2-oxoglutarate 5-dixoygenase (lysine hydroxylase) 2; procollagen-lysine, 2-oxoglutarate 5-dioxy- genase (lysine hydroxy- lase) 2 isoform S0202 PTK7 protein 5754 PTK7; CCK4; protein- LKKPQDSQLE KAKRLQKQP KDRPSFSEIA 1:500- tyrosine tyrosine kinase PTK7; EGKPGYLD EGEEPEME SALGDSTVDS 1:800 kinase 7 colon carcinoma kinase-4; (209) (210) KP (211) PTK7 protein tyrosine kinase 7; PTK7 protein tyrosine kinase 7 isoform e precursor; PTK7 protein tyrosine kinase 7 isoform a precursor; PTK7 protein tryosine kinase 7 isoform d precursor; S0211 cytochrome 1549 CYPIIA; P450-IIA4; KRGIEERIQEE DRVIGKNRQ NPQHFLDDK 1:500- P450, family 1.14.14.1; CPA7; CYP2A7; SGFLIE PKFEDRTK GQFKKSD 1:2500 2, subfamily CPAD; CYTOCHROME P450, (212) (213) (214) A, poly- SUBFAMILY IIA, POLY- peptide 7 PEPTIDE 7; cytochrome P450, subfamily IIA (phenobarbital-inducible), polypeptide 7; cytochrome P450, family 2, subfamily A, polypeptide 7; cyto- chrome P450, family 2, su S0218 solute carrier 222962 SLC29A4; solute carrier RHCILGEWLPI KQRELAGNT RNAHGSCLH 1:20-1:50 family 29 family 29 (nucleoside LIMAVFN MTVSYMS ASTANGSILA (nucleoside transporters), member 4 (215) (216) GL (217) transporters), member 4 S0221 solute carrier 9153 HCNT2; SLC28A2; HsT17153; ELMEKEVEPE KARSFCKTH KNKRLSGME 1:500- family 28 SPNT1; CONCENTRATIVE GSKRTD ARLFNK EWIEGEK 1:1200 (sodium- NUCLEOSIDE TRANSPORTER 2; (218) (219) (220) coupled SODIUM-DEPENDENT PURINE nucleoside NUCLESIDE TRANSPORTER 1; transporter), solute carrier family 28 member 2 (sodium-coupled nucleoside transporter), member 2 S0223 angiopoietin- 51129 HFARP; FIAF; ANGPTL4; EGSTDLPLAP KVAQQQRHL DHKHLDHEV 1:30- like 4 PGAR; angiopoietin-like 4; ESRVDPE EKQHLR AKPARRKRLP 1:10000 FASTING-INDUCED ADIPOSE (221) (222) E (223) FACTOR; PPARG ANGIO- POIETIN-RELATED PROTEIN; HEPATIC FIBRINOGEN/ ANGIOPOIETIN-RELATED PROTEIN S0235 carcino- 1048 CEACAM5; CD66e; carcino- KLTIESTPFNV KSDLVNEEA KPVEDKDAVA 1:500- embryonic embryonic antigen-related AEGKEC TGQFRVYPE FTCEPEAQ 1:4500 antigen- cell adhesion molecule 5 (224) LPK (225) (226) related cell adhesion molecule 5 S0237 podocalyxin- 5420 podocalyxin-like; Gp200; DEKLISLICRA KDKWDELKE DSWIVPLDNL 1:1000- like PCLP; PODXL; PODOCALYXIN- VKATFNPAQDK AGVSDMKLG TKDDLDEEED 1:2000 LIKE PROTEIN; (227) D (228) THL (229) podocalyxin-like precursor S0238 xenotropic 9213 X3; XPR1; X RECEPTOR; EAVVTNELED RRYRDTKRA KARDTKVLIE 1:100- and polytropic SYG1, YEAST. HOMOLOG OF; GDRQKAMKRL FPHLVNAGK DTDDEANT 1:500 retrovirus xenotropic and polytropic R (230) (231) (232) receptor retrovirus receptor S0241 glycyl-tRNA 2617 GlyRS; GARS; CMT2D; RKRVLEAKEL RHGVSHKVD EARYPLFEG 1:500- synthetase 6.1.1.14; SMAD1; GLYCYL- ALQPKDDIVD DSSGSIGRR QETGKKETIE 1:7500 tRNA SYNTHETASE; glycine, (233) YAR (234) E (235) tRNA ligase; Charcot- Marie-Tooth nuuropathy, neuronal type, D S0244 dashshund 1602 DACH1; FLJ0138; dachshund DLAGHDMGH EKQVQLEKT EADRSGGRT 1:100- homolog 1 homolog (Drosophila); ESKRMHIEKD ELKMDFLRE DAETIQDGR 1:3000 (Drosophila) DACHSHUND, DROSOPHILA, E (236) RE (237) (238) HOMOLOG OF; dachshund homolog 1 (Drosophila); dachshund homolog 1 isoform a; dachshund homolog 1 isoform b; dachshund homolog 1 isoform c S0251 transcription 29841 TFCP2L2; LBP-32; MGR; GRHL EALYPQRRSY DYYKVPRER DKYDVPHDI 1:5400 factor CP2- 1; mammailan grainyhead; TSEDEAWK RSSTAKPEV GKIFKKCKK like 2 LBP protein 32; transcrip- (239) E (240) (241) tion factor CP2-like 2; leader-binding protein 32 isoform 2; leader-binding protein 32 isoform 1 S0253 lysosomal 55353 LAPTM4B; lysosomal DPDQYNFSSS EYIRQLPPNF DTTVLLPPYD 1:500- associated associated protein trans- ELGGDFEFMD PYRDD DATVNGAAK 1:2000 protein membrane 4 beta D (242) (243) E (244) transmembrane 4 beta S0255 cyclin E2 9134 CYCE2; CCNE2; cyclin E2; RREEVTKKHQ KESRYVHDK DFFDRFMLT 1:1000- G1/S-specific cyclin E2; YEIR (245) HFEVLHSDLE QKDINK 1:2000 cyclin E2 isoform 2; (246) (247) cyclin E2 isoform 3; cyclin E2 isoform 1 S0260 nicastrin 23385 KIAA0253; nicastrin; ESKHFTRDLM ETDRLPRCV ESRWKDIRA 1:2400- NCSTN; APH2; ANTERIOR EKLKGRTSR RSTARLAR RIFLIASKELE 1:5400 PHARYNX DEFECTIVE 2, (248) (249) (250) C. ELEGANS, HOMOLOG OF S0265 FXYD domain 5349 MAT-8; MAT8; PLML; FXYD3; KVTLGLLVFLA SEWRSSGE KCKCKFGQK 1:400- containing phospholemman-like GFPVLDANDL QAGR (252) SGHHPGE 1:1200 ion transport protien; MAMMARY TUMOR, ED (251) (253) regulator 3 8 KD; FXYD domain- containing ion transport regulator 3; FXYD domain containing ion transport regulator 3; FXYD domain containing ion transport regulator 3 isoform 2 precursor; FXYD domai S0267 immunoglobulin 3321 EWI-3; V8; IGSF3; immuno- KVAKESDSVF EREKTVTGE KRAEDTAGQ 1:200- superfamily, globin superfamily, member VLKIYHLRQED FIDKESKRPK TALTVMRPD 1:250 member 3 3; immunoglobulin (254) (255) (256) superfamily, member 3 S0270 signal trans- 10254 STAM2B; STAM2; KVARKVRALY ETEVAAVDKL EIKKSEPEPV 1:1000- ducing DKFZp564C047; Hbp; STAM2A; DFEAVEDNE NVIDDDVE YIDEDKMDR 1:9000 adaptor SIGNAL-TRANSDUCING ADAPTOR (257) (258) (259) molecule (SH3 MOLECULE 2; signal trans- domain and ducing adaptor molecule 2; ITAM motif) 2 STAM-like protein containing SH3 and ITAM domains 2; signal trans- ducing adaptor molecule (SH3 domain and ITAM motif) 2 S0273 dickkopf 22943 DKK1; DKK-1; SK; dickkopf- DEECGTDEYC RGEIEETITE N/A 1:400- homolog 1 1 like; dickkopf (Xenopus ASPTRGGD SFGNDHSTL 1:500 (Xenopus laevia) homolog 1; (260) D (261) laevis) dickkopf homolog 1 (Xenopus laevis); DICKKOPF, XENOPUS, HOMOLOG OF, 1 S0280 solute carrier 65010 SLC26A6; solute carrier MDLRRRDYH DTDIYRDVAE EFYSDALKQR 1:1800- family 26, family 26, member 6 MERPLLNQEH YSEAKE CGVDVDFLIS 1:2400 member 6 LEE (262) (263) QKKK (264) S0286 WNT inhibitory 11197 WIF1; WIF-1; WNT DAHQARVLIG ERRICECPD KRYEASLIHA 1:90 factor 1 inhibitory factor 1; FEEDLIIVSE GFHGPHCEK LRPAGAQLR Wnt inhibitory factor-1 (265) (266) (267) precursor S0288 preferentially 23532 MAPE; PRAME; OPA-INTER- KRKVDGLSTE KEGACDELF DIKMILKMVQ 1:1200 expressed ACTING PROTEIN 4; Opa- AEQPFIPVE SYLIEKVKRK LDSIEDLE antigen in interacting protein OIP4; (268) K (269) (270) melanoma preferentially expressed antigen in melanoma; melanoma antigen preferentially expressed in tumors S0295 prostaglandin 9536 PGES; TP53I12; MGST1L1; RLRKKAFANP RSDPDVERC RVAHTVAYLG 1:100- E synthase PP1294; PP102; PTGES; EDALR LRAHRND KLRAPIR 1:2400 MGC10317; PIG12; MGST1-L1; (271) (272) (273) MGST-IV; MGST1-like 1; p53-INDUCED GENE 12; prostaglandin E synthase; p53-induced apoptosis protein 12; prostaglandin E synthase isoform 2; prostaglandin E synthase isoform 1; micros S0296 solute carrier 8140 SLC7A5; MPE16; D16S469E; KRRALAAPAA EAREKMLAA MIWLRHRKP 1:300- family 7 CD98; LAT1; 4F2 light EEKEEAR KSADGSAPA ELERPIK 1:5000 (cationic chain; Membrane protein (274) GE (275) (276) amino acid E16; L-TYPE AMINO ACID transporter, TRANSPORTER 1; Solute y+system), carrier family 7, member member 5 5; solute carrier family 7 (cationic amino acid transporter, y+system), member 5 S0296P1 solute carrier 8140 SLC7A5; MPE16; D16S469E; KRRALAAPAA N/A N/A 1:225- family 7 CD98; LAT1; 4F2 light EEKEEAR 1:3150 (cationic chain; Membrane protein (277) amino acid E16; L-TYPE AMINO ACID transporter, TRANSPORTER 1; Solute y+system), carrier family 7, member member 5 5; solute carrier family 7 (cationic amino acid transporter, y+system), member 5 S0297 v-maf 7975 FLJ32205; NFE2U; MAFK; KPNKALKVKK KRVTQKEEL RLELDALRSK 1:333- musculoapon- NFE2, 18 KD SUBUNIT; EAGE (278) ERQRVELQQ YE (280) 1:800 eurotic nuclear factor erythroid- EVEK (279) fibrosarcoma 2, ubiquitous (p18); oncogene NUCLEAR FACTOR ERYTHROID homolog K 2, UBIQUITOUS SUBUNIT; (avian) v-maf musculoapoeurotic fibrosarcoma oncogene homolog K (avian); v-maf avian musculoaponeurotic fibrosarcoma oncogen S0301 signal pep- 57758 SCUBE2; signal peptide, KMHTDGRSCL KKGFKLLTDE KRTEKRLRKA 1:3500- tide, CUB CUB domain, EGF-like 2 EREDTVLEVT KSCQDVDE IRTLRKAVHR 1:5400 domain, EGF- E (281) (282) E (283) like 2 S0303 gamma-amino- 2564 GABRE; GABA-A RECEPTOR, RVEGPQTESK EETKSTETET KWENFKLEIN 1:300- butyric acid EPSILON POLYPEPTIDE; NEASSRD GSRVGKLPE EKNSWKLFQ 1:500 (GABA) A GAMMA-AMINOBUTYRIC ACID (284) (285) FD (286) receptor, RECEPTOR, EPSILON; gamma- epsilon aminobutyric acid (GABA) A receptor, epsilon; gamma- aminobutyric acid (GABA) A receptor, epsilon isoform 2; gamma-aminobutyric acid (GABA) A receptor, epsilon is S0305 S100 calcium 6281 CAL1L; GP11; p10; 42C; DKGYLTKEDL KDPLAVDKIM N/A 1:8332- binding S100A10; ANX2LG; CLP11; RVLMEKE KDLDQCRDG 1:24996 protein A10 Ca[1]; CALPACTIN I, (287) K (288) (annexin II p11 SUBUNIT; ANNEXIN II, ligand, LIGHT CHAIN; CALPACTIN I, calpactin I, LIGHT CHAIN; S100 calcium- light poly- binding protein A10 peptide (p11)) (annexin II ligand, calpactin I, light polypeptide (p11); S100 calcium binding protein A10 S0311 v-myb 4605 MYBL2; MGC15600; MYB- MSRRTRCEDL EEDLKEVLRS RRSPIKKVRK 1:750- myeloblastosis RELATED GENE BMYB; MYB- DELHYQDTDS EAGIELIIEDD SLALDIVDED 1:5000 viral onco- related protein B; v-myb D (289) IR (290) (291) gene homolog myeloblastosis viral (avian)-like oncogene homolog (avian)- 2 like 2; V-MYB AVIAN MYELOBLASTOSIS VIRAL ONCOGENE HOMOLOG-LIKE 2 S0312 nucleoside 4860 NP; 2.42.1; nucleoside EDYKNTAEWL DERFGDRFP KVIMDYESLE 1:100- phosphorylase phosphorylase; PURINE- LSHTKHR AMSDAYDRT KANHEE 1:3600 NUCLEOSIDE:ORTHOPHOSPHATE (292) MRQR (293) (294) RIBOSYLTRANSFERASE; purine nucleoside phosphorylase; PNP NUCLEOSIDE PHOSPHORYLASE DEFIENCY; ATAXIA WITH DEFICIENT CELLULAR IMMUNITY S0314 chaperonin 22948 KIAA0098; CCt5; chaperonin DQDRKSRLM KGVIVDKDFS RMILKIDDIRK 1:6000- containing containing TCP1, subunit 5 GLEALKSHIMA HPQMPKKVE PGESEE 1:30000 TCP1, subunit (epsilon) AK (295) D (296) (297) 5 (epsilon) S0315 non- 4830 GAAD; NME1; NDPKA; 2.74.6; RLQPEFKPKQ KFMQASEDL DSVESAEKEI 1:9000- metastatic NM23-H1; AWD NM23H1B; LEGTMANCER LKEHYVDLKD GLWFHPEEL 1:18000 cells 1, GZMA-ACTIVATED DNase; (298) R (299) VD (300) protein NUCLEOSIDE DIPHOSPHATE (NM23A) KINASE-A; AWD, DROSOPHILA, epressed in HOMOLOG OF; METASTASIS INHIBITION FACTOR NM23; nucleoside-diphosphate kinase 1 isoform b; NONMETASTATIC PROTEIN 23, HOMOLOG 1; nucleo S0316 squalene 6713 SQLE; 1.14.99.7; squalene KSPPESENKE RDGRKVTVIE DHLKEPFLEA 1:1000- epoxidase epoxidase; squalene QLEAPPPP RDLKEPDR TDNSHLR 1:10000 monooxygenase (301) (302) (303) S0319 pregnancy- 29948 OKL38; pregnancy-induced DLEVKDWMQ EYHKVHQMM RHQLLCFKED 1:900 induced growth inhibitor; KKRRGLRNSR REQSILSPSP CQAVFQDLE growth PREGNANCY-INDUCED GROWTH (304) YEGYR (305) GVEK (306) inhibitor INHIBITOR OKL38 S0326 mal, T-cell 114569 MAL2; mal, T-cell dif- GPDILRTYSGA CSLGLALRR N/A 1:120- differentia- ferentiation protein 2 FVCLE (307) WRP (308) 1:1200 tion protein 2 S0330 aldo-keto 1645 1.1.1.213; 2-ALPHA-HSD; RYLTLDIFAGP N/A N/A 1:2500- reductase 1.3.1.20; 20-ALPHA-HSD; PNYPFSDEY 1:75000 family 1, MGC8954; H-37 HAKRC; MBAB; (309) member C1/2 C9; DDH1; AKR1C1; trans- (dihydrodiol 1,2-dihydrobenzene-1,2- dehydrogenase diol dehydrogenase; 1; 20-alpha chlordecone reductase (3-alpha)- homolog; aldo-keto hydroxysteroid reductase C; 20 alpha- dehydrohenase) hydroxysteroid dehydro- genase; hepatic dihydrodiol S0330-x1 aldo-keto 1645 1.1.1.213; 2-ALPHA-HSD; RYLTLDIFAGP N/A N/A 1:600 reductase 1.3.1.20; 20-ALPHA-HSD; PNYPFSDEY family 1, MGC8954; H-37 HAKRC; MBAB; (310) member C1/2 C9; DDH1; AKR1C1; trans- (dihydrodiol 1,2-dihydrobenzene-1,2- dehydrogenase diol dehydrogenase; 1; 20-alpha chlordecone reductase (3-alpha)- homolog; aldo-keto hydroxysteroid reductase C; 20 alpha- dehydrohenase) hydroxysteroid dehydro- genase; hepatic dihydrodiol S0331 aldo-keto 8644 HA1753; 1.1.1.188; DD3; HYFNSDSFAS N/A N/A 1:300- reductase hluPGFS; HSD17B5; 1.31.20; HPNYPYSDEY 1:999 family 1, 1.1.1.213; AKR1C3; (311) member C3 KIAA0119; HAKRB; HAKRe; (3-alpha trans-1,2-dihydrobenzene- hydroxysteroid 1,2-diol dehydrogenase; dehydrogenase, chlordecone reductase type II) homolog; dihydrodiol, dehydrogenase 3; prostaglandin F synthase; ALDO-KETO REDUCTASE B; 3- S0331-x1 aldo-keto 8644 HA1753; 1.1.1.188; DD3; HYFNSDSFAS N/A N/A 1:150- reductase hluPGFS; HSD17B5; 1.31.20; HPNYPYSDEY 1:300 family 1, 1.1.1.213; AKR1C3; (312) member C3 KIAA0119; HAKRB; HAKRe; (3-alpha trans-1,2-dihydrobenzene- hydroxysteroid 1,2-diol dehydrogenase; dehydrogenase, chlordecone reductase type II) homolog; dihydrodiol, dehydrogenase 3; prostaglandin F synthase; ALDO-KETO REDUCTASE B; 3- S0332 aldo-keto 1645 1.1.1.213; 2-ALPHA-HSD; RYVVMDFLMD N/A N/A 1:300- reductase 1.3.1.20; 20-ALPHA-HSD; HPDYPFSDEY 1:400 family 1, MGC8954; H-37; HAKRC; (313) member C4 MBAB; C9; DDH1; AKR1C1; (dihydrodiol trans-1,2-dihydrobenzene- dehydrogenase 1,2-diol dehydrogenase; 1; 20-alpha chlordecone reductase (3-alpha)- homolog; aldo-keto hydroxysteroid reductase C; 20 alpha- dehydrogenase) hydrocysteroid dehydro- genase; hepatic dihydrodiol S0332-x1 aldo-keto 1645 1.1.1.213; 2-ALPHA-HSD; RYVVMDFLMD N/A N/A 1:75- reductase 1.3.1.20; 20-ALPHA-HSD; HPDYPFSDEY 1:150 family 1, MGC8954; H-37; HAKRC; (314) member C4 MBAB; C9; DDH1; AKR1C1; (dihydrodiol trans-1,2-dihydrobenzene- dehydrogenase 1,2-diol dehydrogenase; 1; 20-alpha chlordecone reductase (3-alpha)- homolog; aldo-keto hydroxysteroid reductase C; 20 alpha- dehydrogenase) hydrocysteroid dehydro- genase; hepatic dihydrodiol S0336 chromosome 20 140809 C20orf139; chromosome 20 DPAKVQSLVD RETIPAKLVQ N/A 1:600- open reading open reading frame 139 TIREDPD STLSDLR 1:2400 frame 139 (315) (316) S0342 solute carrier 154091 SLC2A12; solute carrier SDTTEELTVIK N/A N/A 1:400- family 2 family 2 (facilitated SSLKDE 1:1250 (facilitated glucose transporter), (317) glucose trans- member 12 porter), member 12 S0343 solute carrier 154091 SLC2A12; solute carrier HSRSSLMPLR N/A N/A 1:50- family 2 family 2 (facilitated NDVDKR 1:125 (facilitated glucose transporter), (318) glucose trans- member 12 porter), member 12 S0357 HTPAP protein 84513 HTPAP; HTPAP protein YRNPYVEAEY N/A N/A 1:100- FPTKPMFVIA 1:300 (319) S0364 KIAA0746 23231 KIAA0746; KIAA0746 KKFPRFRNRE N/A N/A 1:200- protein protein LEATRRQRMD 1:300 (320) S0367 peroxisomal 122970 PTE2B; peroxisomal acyl- SGNTAINYKH N/A N/A 1:200- acyl-CoA CoA thioesterase 2B SSIP (321) 1:600 thioesterase 2B S0374 chloride 53405 CLIC5; chloride intra- DANTCGEDKG N/A N/A 1:5000- intracellular cellular channel 5 SRRKFLDGDE 1:9000 channel 5 (322) S0380 keratinocyte 200634 KRTCAP3; keratinocyte QLEEMTELES N/A N/A 1:200- associated associated protein 3 PKCKRQENEQ 1:9000 protein 3 (323) S0384 FERM, RhoGEF 10160 p63RHoGEF; CDEP; FARP1; QADGAASAPT N/A N/A 1:100 (ARHGEF) and chondrocyte-derived ezrin- EEEEEVVKDR pleckstrin like protein; FERM, (324) domain RhoGEF, and pleckstrin protein 1 domain protein 1; FERM, (chondrocyte- ARHGEF, AND PLECKSTRIN derived) DOMAIN-CONTAINING PROTEIN 1; FERM, RhoGEF (ARHGEF) and pleckstrin domain protein 1 (chondrocyte- derived) S0388 trichorhino- 7227 GC79; TRPS1; TRPS1 GENE; SGDSLETKED N/A N/A 1:600 phalangeal trichorhinophalangeal QKMSPKATEE syndrome I syndrome I; zinc finger (325) transcription factor TRPS1 S0396 cytochrome 1576 1.114.14.1; HLP; CYPA3; RKSVKRMKES N/A N/A 1:15 P450, family CYP3A4; P450C3; NF-25; RLEDTQKHRV 3, subfamily CP33; CP34; P450-III, (326) A, polypeptide STEROID-INDUCIBLE; 4 nifedipine oxidase; glucocorticoid-inducible P450, CYTOCHROME P450PCN1; P450, FAMILY III; P450-III, steroid inducible; cytochrome P450, subfamily IIIA, polypeptide 4; S0398 FAT tumor 2195 CDHF7; FAT; cadherin ME5; KIRLPEREKPD N/A N/A 1:45- suppressor FAT tumor suppressor RERNARREP 1:200 homolog 1 precursor; cadherin- (327) (Drosophila) related tumor suppressor homolog precursor; cadherin family member 7 precursor; homolog of Drosophila Fat protein precursor; FAT tumor suppressor homolog 1 (Drosophila); FAT TUMOR SUPPRESS S0401 granulin 2896 ACROGRANIN; PROEPITHELIN; RGTKCLRREA N/A N/A 1:600- PROGRANULIN; PEPI; PCDGF; PRWDAPLRDP 1:3000 granulin; GRN; EPITHELIN (328) PRECURSOR S0404 N-myc down- 10397 HMSNL; TARG1; CMT4D; RTP; GTRSRSHTSE N/A N/A 1:100- stream PROXY1; NDRG1; GC4; NMSL; GTRSRSHTSE 1:900 regulated TDD5; RIT42; NDR1; (329) gene 1 differentiation-related gene 1 protein; nickel- specific induction protein Cap43; protein regulated by oxygen 1; NMYC DOWN- STREAM-REGULATED GENE 1; reducing agents and tunicamycin-respon S0411 fatty acid 2171 PAFABP; EFABP; E-FABP; EETTADGRKT N/A N/A 1:1800 binding FABP5; PA-FABP; FATTY QTVCNFTD protein 5 ACID-BINDING PROTEIN; (330) (psoriasis- EPIDERMAL; FATTY ACID- associated) BINDING PROTEIN 5; FATTY ACID-BINDING PROTEIN, PSORIASIS-ASSOCIATED; fatty acid binding protein 5 (psoriasis-associated) S0413 cyclin- 1028 WBS; p57(KIP2); BWCR; AKRKRSAPEK N/A N/A 1:2700 dependent CDKN1C; BWS; Beckwith- SSGDVP kinase Wiedemann syndrome; (331) inhibitor 1C cyclin-dependent kinase (p57, Kip2) inhibitor 1C (p57, Kip2) S0414 alpha- 23600 AMACR; 5.1.99.4; ALPHA- RVDRPGSRYD N/A N/A 1:100 methylacyl-CoA METHYLACYL-CoA RACEMASE; VSRLGRGKRS racemase AMACR DEFICIENCY; AMACR (332) ALPHA-METHYLACYL-CoA RACEMASE DEFICIENCY; alpha-methylacyl-CoA racemase isoform 1; alpha-methylacyl-CoA racemase isoform 2 S0415 gamma- 2562 MGC9051; GABRB3; GABA-A ETVDKLLKGY N/A N/A 1:600- aminobutyric RECEPTOR, BETA-3 POLY- DIRLRPD 1:1800 acid (GABA) PEPTIDE; GAMMA-AMINO- (333) A receptor, BUTYRIC ACID RECEPTOR, beta 3 BETA-3; gamma-aminobutyric acid (GABA) A receptor, beta 3; gamma-aminoburyric acid (GABA) A receptor, beta 3 isoform 2 precursor; gamma-amino- butyric acid (GABA) A rece S0417 HSV-1 22879 HDRG1; KIAA0872; HSV-1 APGGAEDLED N/A N/A 1:9000 stimulation- stimulation-related 1; TQFPSEEARE related gene 1 HSV-1 stimulation- (334) related gene 1 S0425 tumor necrosis 27242 TNFRSF21; DR6; BM-018; RKSSRTLKKG N/A N/A 1:9000 factor TNFR-related death PRQDPSAIVE receptor receptor 6; tumor necrosis (335) superfamily, factor receptor super- member 21 family, member 21; tumor necrosis factor receptor superfamily, member 21 precursor S0429 jumonji domain 221037 JMJD1C; TRIP8; jumonji GSESGDSDES N/A N/A 1:1200 containing 1C domain containing 1C; ESKSEQRTKR THYROID HORMONE RECEPTOR (336) INTERACTOR 8 S0432 chromosome 9 null C9orf140; chromosome 9 EADSGDARRL N/A N/A 1:90- open reading open reading frame 140 PRARGERRRH 1:300 frame 140 (337) S0440 cell division 994 3.1.3.48; CDC25B; cell RLERPQDRDT N/A N/A 1:350- cycle 25B division cycle 25B; cell PVQNKRRRS 1:3600 division cycle 25B isoform (338) 4; cell division cycle 25B isoform 5; cell division cycle 25B isoform 1; cell division cycle 25B isoform 2; cell division cycle 25B isoform 3 S0445 laminin, beta 3912 LAMB1; LAMININ, BETA-1; DRVEDVMME N/A N/A 1:600- 1 CUTIS LAXA-MARFANOID RESQFKEKQE 1:1800 SYNDROME; laminin, beta 1; (339) laminin, beta 1 precursor; LAMB1 NEONATAL CUTIS LAXA WITH MARFANOID PHENOTYPE S0447 papillary 5546 TPRC; MGC17178; MGC4723; DEAFKRLQGK N/A N/A 1:4000- renal cell PRCC; proline-rich PRCC; RNRGREE 1:6000 carcinoma RCCP1 PRCC/TFE3 FUSION (340) (trans- GENE; papillary renal cell location- carcinoma (translocation- associataed) associatied); RENAL CELL CARCINOMA, PAPILLARY, 1 GENE; papillary renal cell carcinoma translocation- associated gene product S0455 tumor necrosis 8743 APO2L; TL2; Apo-2L; RFQEEIKENTK N/A N/A 1:900 factor TNFSF10; Apo-2 ligand; NDKQ (341) (ligand) APO2 LIGAND; TNF-RELATED superfamily, APOPTOSIS-INDUCING LIGAND; member 10 TNF-related apoptosis inducing ligand TRAIL; tumor necrosis factor (ligand) superfamily, member 10; TUMOR NECROSIS FACTOR LIGAND SUPERFAMILY, MEMBER 10 S0459 titin 7273 connectin; TMD; titin; KRDKEGVRW N/A N/A 1:2700- CMD1G; CMPD4; TTN; TKCNKKTLTD 1:8100 FLJ32040; CMH9, included; (342) titin isoform N2-A; titin isoform N2-B; titin isoform novex-1; titin isoform novex-2; titin isoform novex-3; cardio- myopathy, dilated 1G (autosomal dominant); TTN CARDIOMYOPATHY, FAMILIAL S0469 DNA fragmenta- 1676 DFF45; DFF1; DFFA; ICAD; KEGSLLSKQE N/A N/A 1:600 tion factor, DFF-45; INHIBITOR OF ESKAAFGEE 45 kDa, alpha CASPASE-ACTIVATED DNase; (343) polypeptide DNA FRAGMENTATION FACTOR, 45 KD, ALPHA SUBUNIT; DNA fragmentation factor, 45 kDa, alpha polypeptide; DNA fragmentation factor, 45 kD, alpha subunit; DNA fragmentation factor, 45 kD, alp S0494 caspase 2, 835 ICH-1L/1S; CASP2; ICH1; ESDAGKEKLP N/A N/A 1:2000 apoptosis- CASP-2; ICH-1 protease; KMRLPTRSD related caspase 2 isoform 3; (334) cysteine pro- caspase 2 isoform 4; NEDD2 tease (neural apoptosis regulatory gene; precursor cell caspase 2 isoform 2 expressed, precursor; caspase 2 developmental- isoform 1 preproprotein; ly down- NEURAL PRECURSOR CELL regulated 2) EXPRESSED, DEVELOPMENTALLY DOWNREGULATED 2; S0501 G1 to S phase 2935 GSPT1; eRF3a; ETF3A; GST1, ERDKGKTVEV N/A N/A 1:15000 transition 1 YEAST, HOMOLOG OF; PEPTIDE GRAYFETEK CHAIN RELEASE FACTOR 3A; (345) G1- TO S-PHASE TRANSITION 1; G1 to S phase transition 1 S0502 GCN5 general 2648 hGCN5; GCN5L2; GCN5 EKFRVEKDKL N/A N/A 1:9000 control of (general control of VPEKR amino-acid amino-acid synthesis, (346) synthesis 5- yeast, homolog)-like 2; like 2 GCN5 general control of (yeast) amino-acid synthesis 5- like 2 (yeast); General control of amino acid synthesis, yeast, homolog- like 2 S0503 geminin, DNA 51053 GMNN; geminin, DNA EVAEKRRKAL N/A N/A 1:333 replication replication inhibitor YEALKENEK inhibitor (347) S0507 ADP-ribo- 64225 ARL6IP2; ADP-ribosylation ENYEDDDLVN N/A N/A 1:8000- sylation factor-like 6 interacting SDEVMKKP 1:9000 factor-like protein 2 (348) 6 interacting protein 2 S0511 DNA replica- 51659 Pfs2; DNA replication PKADEIRTLVK N/A N/A 1:2000 tion complex complex GINS protein PSF2 DMWDTR GINS protein (349) PSF2 S0524 ankyrin repeat 55608 ANKRD10; ankyrin repeat RKRCLEDSED N/A N/A 1:4500 domain 10 domain 10 FGVKKARTE (350) S0527 potassium null KCTD2; potassium channel EPKSFLCRLC N/A N/A 1:900- channel tetra- tetramerisation domain CQEDPELDS 1:1500 merisation containing 2 (351) domain con- taining 2 S0528 rabconnecin-3 23312 RC3; KIAA0856; EEYDRESKSS N/A N/A 1:350- rabconnectin-3 DDVDYRGS 1:1200 (352) S0538 acidic 81611 ANP32E; acidic (leucine- CVNGEIEGLN N/A N/A 1:1200 (leucine-rich) rich) nuclear phospho- DTFKELEF nuclear protein 32 family, (353) phosphoprotein member E 32 family member E S0544 chromosome 9 84904 C9orf100; chromosome 9 EQRARWERK N/A N/A 1:40- open reading open reading frame 100 RACTARE 1:240 frame 100 (354) S0545 Hpall tiny 27037 D22S1733E; HTF9C; Hpall ERKQLECEQV N/A N/A 1:900- fragments tiny fragments locus 9C; LQKLAKE 1:5400 locus 9C Hpall tiny fragments locus (355) 9C isoform2; Hpall tiny fragments locus 9C isoform 1 S0546 cell division 157313 CDCA2; cell division cycle RNSETKVRRS N/A N/A 1:1200 cycle associated 2 TRLQKDLEN associaed 2 (356) S0553 mitotic 129401 MP44; NUP35; LOC129401; SDYQVISDRQ N/A N/A 1:3000- phosphoprotein NUCLEOPORIN TPKKDE 1:5400 44 35 KD; mitotic (357) phosphoprotein 44 S0557 SMC4 10051 SMC4L; CAPC; hCAP-C; DIEGKLPQTE N/A N/A 1:200 structural chromosome-associated QELKE maintenance of polypeptide C; SMC4 (358) chromosomes 4- (structural maintenance like 1 (yeast) of chromosomes 4, yeast)- like 1; SMC4 structural maintenance of chromosomes 4-like 1 (yeast); structural maintenance of chromosomes (SMC) family member, chromosome-ass S0564 phosphatidyl- 9791 KIAA0024; PSSA; PTDSS1; DDVNYKMHFR N/A N/A 1:100- serine phosphatidylserine MINEQQVED 1:8000 synthase 1 synthase 1 (359) S0565 polo-like 5347 2.7.1-; PLK1; STPK13; ENPLPERPRE N/A N/A 1:10- kinase 1 polo-like kinase KEEPVVR 1:100 (Drosophilia) (Drosophila); polo (360) (Drosophila)-like kinase; SERINE/THREONINE PROTEIN KINASE 13; polo- like kinase 1 (Drosophila) S0567 Pirin 8544 Pirin; PIR REQSEGVGAR N/A N/A 1:240 VRRSIGRPE (361) S0578 ATP-binding 21 ABCA3; ABC3; LBM180; PRAVAGKEEE N/A N/A 1:1500 cassette, ABC-C; EST111653; ABC DSDPEKALR sub-family A transporter 3; ATP- (362) (ABC1), binding cassette 3; ATP- member 3 BINDING CASSETTE TRANS- PORTER 3; ATP-BINDING CASSETTE, SUBFAMILY A, MEMBER 3; ATP-binding cassette, sub-family A member 3; ATP-binding cassette, sub-family A (ABC1), memb S0579 ATP-binding 10347 ABCX; ABCA7; ABCA-SSN; EKADTDMEGS N/A N/A 1:300- cassette, sub- autoantigen SS-N; macro- VDTRQEK 1:400 family A phage ABC transporter; (363) (ABC1), SJOGREN SYNDROME ANTIGEN member 7 SS-N; ATP-BINDING CASSETTE, SUBFAMILY A, MEMBER 7; ATP-binding cassette, sub-family A (ABC1), member 7; ATP- binding cassette, sub- family A, member 7 isoform a; A S0581 ATP-binding 22 ABCB7; Atm1p; ASAT; ABC7; RVQNHDNPK N/A N/A 1:4000- cassette, EST140535; ABC TRANSPORTER WEAKKENISK 1:10000 sub-family B 7; ATP-binding cassette 7; (364) (MDR/TAP), ATP-BINDING CASSETTE member 7 TRANSPORTER 7; Anemia, sideroblastic, with spino- cerebellar ataxia; ATP- BINDING CASSETTE, SUBFAMILY B, MEMBER 7; ATP-binding cassette, sub-family B, member S0585 ATP-binding 94160 MRP9; ABCC12; MULTIDRUG RSPPAKGATG N/A N/A 1:500 cassette, RESISTANCE-ASSOCIATED 9; PEEQSDSLK sub-family C ATP-BINDING CASSETTE, (365) (CFTR/MRP), SUBFAMILY C, MEMBER 12; member 12 ATP-binding cassette, sub- family C (CFTR/MRP), member 12 S0586 ATP-binding 9429 ABC15; MXR1; ABCP; REEDFKATEII N/A N/A 1:333- cassette, EST157481; MRX; ABCG2; EPSKQDKP 1:400 sub-family G BCRP1; BMDP; MITOXANTRONE- (366) (WHITE), RESISTANCE PROTEIN; member 2 mitoxantrone resistance protein; placenta specific MDR protein; ATP-BINDING CASSETTE TRANSPORTER, PLACENTA-SPECIFIC; breast cancer resistance protein; ATP-BINDING CASS S0593 solute carrier 28234 OATP1B3; SLC21A8; OATP8; DKTCMKWST N/A N/A 1:500- organic anion SLCO1B3; ORGANIC ANION NSCGAQ 1:2400 transporter TRANSPORTER 8; solute (367) family, carrier organic anion member 1B3 transporter family, member 1B3; SOLUTE CARRIER FAMILY 21, MEMBER 8 (ORGANIC ANION TRANSPORTER); solute carrier family 21 (organic anion transporter), member 8 S0597 solute carrier 9356 ROAT1; MGC45260; HOAT1; DANLSKNGGL N/A N/A 1:3000 family 22 PAHT; SLC22A6; PAH EVWL (368) (organic anion TRANSPORTER; para-amino- transporter), hippurate transporter; member 6 renal organic anion transporter 1; solute carrier family 22 member 6 isoform b; solute carrier family 22 member 6 isoform c; solute carrier family 22 member 6 isoform S0604 solute carrier 7355 UGT2; UGTL; UGAT; SLC35A2; EPFLPKLLTK N/A N/A 1:2400 family 35 UGT1; UDP-galactose (369) (UDP- translocator, UDP- galactose GALACTOSE TRANSPORTER, transporter), ISOFORM 2; UGALT UDP- member A2 GALACTOSE TRANSPORTER, ISOFORM 1; solute carrier family 35 (UDP-galactose transporter), member A2; solute carrier family 35 (UDP-galactose transpo S0607 cell division 994 3.1.3.48; CDC25B; cell RKSEAGSGAA N/A N/A 1:1800 cycle 25B division cycle 25B; cell SSSGEDKEN division cycle 25B isoform (370) 4; cell division cycle 25B isoform 5; cell division cycle 25B isoform 1; cell division cycle 25B isoform 2; cell division cycle 25B isoform 3 S0609 stearoyl-CoA 6319 SCD; acyl-CoA desaturase; DDIYDPTYKDK N/A N/A 1:2000- desaturase stearoly-CoA desaturase EGPSPKVE 1:5000 (delta-9- (delta-9-desaturase); (371) desaturase) fatty acid desaturase S0611 mitogen- 6300 SAPK3; p38gamma; SAPK-3; QSDEAKNNMK N/A N/A 1:100 activated p38-GAMMA; PRKM12; MAPK12; GLPELEKKD protein ERK3; ERK6; EXTRACELLULAR (372) kinase 12 SIGNAL-REGULATED KINASE 6; mitogen-activated protein kinase 3; stress-activated protein kinase 3; mitogen- activated protein kinase 12 S0612 nuclear factor 4791 LYT-10; LYT10; NFKB2; SRPQGLTEAE N/A N/A 1:4500 of kappa ONCOGENE LYT 10; QRELEQEAK light poly- TRANSCRIPTION FACTOR (373) peptide gene NFKB2; NFKB, p52/p100 enhancer in SUBUNIT; LYMPHOCYTE B-cells 2 TRANSLOCATION CHROMOSOME (p49/p100) 10; NUCLEAR FACTOR KAPPA-B, SUBUNIT 2; Nuclear factor of kappa light chain gene enhancer in B-cells 2; nuclear factor of kappa I S0613 tumor necrosis 958 Bp50; TNFRSF5; MGC9013; RVQQKGTSET N/A N/A 1:250- factor CDW40; CD40 antigen; CD40L DTIC (374) 1:270 receptor receptor, B CELL- superfamily, ASSOCIATED MOLECULE CD40; member 5 CD40 type II isoform; B cell surface antigen CD40; nerve growth factor receptor-related B- lymphocyte activation molecule; tumor necrosis factor receptor superfam S0614 Epstein-Barr 10148 EBI3; IL27, EBI3 SUBUNIT; VRLSPLAERQ N/A N/A 1:1200- virus induced EPSTEIN-BARR VIRUS-INDUCED LQVQWE 1:3000 gene 3 GENE 3; INTERLEUKIN 27, (375) EBI3 SUBUNIT; Epstein-Barr virus induced gene 3; Epstein-Barr virus induced gene 3 precursor S0616 zinc finger 58495 ZNF339; zinc finger RRSLGVSVRS N/A N/A 1:2500 protein 339 protein 339 WDELPDEKR (376) S0617 DAB2 153090 DAB2IP; DAB2 interacting DEGLGPDPPH N/A N/A 1:600 interacting protein RDRLRSK protein (377) S0618 protein 8500 MGC26800; LIP1; PPFIA1; SGKRSSDGSL N/A N/A 1:150 tyrosine LIP.1; LAR-interacting SHEEDLAK phosphatase, protein 1; PTPRF (378) receptor type, interacting protein alpha f polypeptide 1 isoform a; PTPRF (PTPRF), interacting protein alpha interacting 1 isoform b; protein protein tyrosine phosphatase, (liprin), receptor type, f poly- alpha 1 peptide (PTPRF), inter- acting protein (liprin), alpha 1 S0631 RGM domain 56963 RGMA; REPULSIVE GUIDANCE SQERSDSPEI N/A N/A 1:600 family, member MOLECULE; RGM domain CHYEKSFHK A family, member A (379) S0633 hypothetical 144347 LOC144347; hypothetical KVNPEPTHEIR N/A N/A 1:100- protein protein LOC144347 CNSEVK 1:200 LOC144347 (380) S0639 tetratrico- 57217 TTC7; tetratricopeptide RELREVLRTV N/A N/A 1:2000- peptide repeat domain 7 ETKATQN 1:3000 repeat (381) domain 7 S0640 protein C 5624 PROC; 3.4.21.69; PROC RDTEDQEDQV N/A N/A 1:1000- (inactivator DEFIENCY PROTEIN C; DPRLIDGK 1:1800 of coagula- THROMBOPHILIA, (382) tion factors HEREDITARY, DUE TO PC Va and VIIIa) DEFINCIENCY; PROTEIN C DEFINCIENCY, CONGENITAL THROMBOTIC DISEASE DUE TO; protein C (inactivator of coagulation factors Va and VIIIa) S0643 transducin- 7090 HsT18976; KIAA1547; ESG3; KNHHELDHRE N/A N/A 1:200- like enhancer TLE3; transducin-like RESSAN 1:1440 of split 3 enhancer protein 3; (383) (E(sp1) enhancer of split groucho homolog, 3; transducin-like en- Drosophila) hancer of split 3 (E(sp1) homolog, Drosophila) S0645 frizzled 8324 FzE3; FZD7; frizzled 7; SDGRGRPAFP N/A N/A 1:900 homolog 7 frizzled homolog 7 FSCPRQ (Drosophila) (Drosophila); Frizzled, (384) drosophila, homolog of, 7 S0646 solute carrier 6520 MDU1; 4T2HC; SLC3A2; GSKEDFDSLL N/A N/A 1:3600- family 3 NACAE; 4F2HC; 4F2 HEAVY QSAKK 1:5400 (activators of CHAIN; CD98 HEAVY CHAIN; (385) dibasic and CD98 MONOCLONAL ANTIBODY neutral amino 44D7; ANTIGEN DEFINED BY acid trans- MONOCLONAL ANTIBODY 4F2, port), member HEAVY CHAIN; antigen 2 identified by monoclonal antibodies 4F2, TRA1.10, TROP4, and T43; SOLUTE CARRIER FAMILY 3 S0648 KIAA0738 gene 9747 KIAA0738; KIAA0738 gene EYRNQTNLPT N/A N/A 1:200 product product ENVDK (386) S0651 phospholipase 22925 PLA2IR; PLA2-R; PLA2R1; QKEEKTWHEA N/A N/A 1:3600 A2 receptor PLA2G1R; PHOSPHOLIPASE LRSCQADN 1, 180 kDa A2 RECEPTOR, 180 KD; (387) phospholipase A2 receptor 1, 180 kDa S0654 KIAA0182 23199 KIAA0182; KIAA0182 protein EKAEEGPRKR N/A N/A 1:400 protein EPAPLDK (388) S0659 thymidine 7084 TK2; THYMIDINE KINASE, EQNRDRILTPE N/A N/A 1:300 kinase 2, MITOCHONDRIAL; thymidine NRK (389) mitochondrial kinase 2, mitochondrial S0663 chromosome 14 64430 C14orf135; chromosome 14 RDWYIGLVSD N/A N/A 1:900 open reading open reading frame 135 EKWK frame 135 (390) S0665 KIAA1007 23019 KIAA1007; KIAA1007 DSYLKTRSPV N/A N/A 1:1500- protein protein; adrenal gland TFLSDLR 1:3000 protein AD-005; KIAA1007 (391) protein isoform a; KIAA1007 protein isoform b S0670 DKFZ566O1646 25936 DC8; DKFZP566O1646 protein KCRGETVAKEI N/A N/A 1:900 protein SEAMKS (392) S0672 B-cell CLL/ 605 BCL7A; B-cell CLL/ QRGSQIGREPI N/A N/A 1:800 lymphoma 7A lymphoma-7; B-cell CLL/ GLSGD lymphoma 7A (393) S0673 likely ortho- 28987 ART-4; NOB1P; adenocar- KPPQETEKGH N/A N/A 1:50 log of mouse cinoma antigen recognized SACEPEN nin one by T lymphocytes 4; likely (394) binding ortholog of mouse nin one protein binding protein S0676 guanine 2768 RMP; NNX3; GNA12; GUANINE ERRAGSGARD N/A N/A 1:1200- nucleotide NUCLEOTIDE-BINDING AERE 1:2400 binding PROTEIN, ALPHA-12; guanine (395) protein (G nucleotide binding protein protein) alpha (G protein) alpha 12 12 S0677 GrpE-like 1, 80273 HMGE; GRPEL1; HUMAN MIRO- SEQKADPPAT N/A N/A 1:500- mitochondrial CHONDRIAL GrpE PROTEIN; EKTLLE 1:1000 (E. coli) GrpE-like 1, mitochondrial (396) (E. coli); GrpE, E. COLI, HOMOLOG OF, 1 S0684 hypothetical 91607 FLJ34922; hypothetical EAEWSQGVQ N/A N/A 1:8100 protein protein FLJ34922 GTLRIKKYLT FLJ34922 (397) S0687 hypothetical 54942 FLJ20457; hypothetical EESKSITEGLL N/A N/A 1:600- protein protein FLJ20457 TQKQYE 1:1260 FLJ20457 (398) S0691 solute carrier 23657 CCBR1; SLC7A11; xCT; QNFKDAFSGR N/A N/A 1:1000- family 7, cystine/glutamate DSSITR 1:1575 (cationic transporter; SYSTEM Xc(−) (399) amino acid TRANSPORTER-RELATED transporter, PROTEIN; SOLUTE CARRIER y+system) FAMILY 7, MEMBER 11; member 11 solute carrier family 7, (cationic amino acid transporter, y+system) member 11 S0692 glutamate- 2729 GLCLC; GCLC; 6.3.2.2; GCS; EKIHLDDANES N/A N/A 1:100- cysteine GAMMA-GLUTAMYLCYSTEINE DHFEN 1:400 ligase, SYNTHETASE, CATALYTIC (400) catalytic SUBUNIT; glutamate- subunit cysteine ligase, catalytic subunit S0695 integrin, beta 3691 ITGB4; INTEGRIN, BETA-4; TEDVDEFRNK N/A N/A 1:2700- 4 integrin, beta 4 LQGER 1:4050 (401) S0702 solute carrier 8140 SLC7A5; MPE16; D16S469E; KGDVSNLDPN N/A N/A 1:21160- family 7 CD98; LAT1; 4F2 light FSFEGTKLDV 1:178200 (cationic chain; Membrane protein (402) amino acid E16; L-TYPE AMINO ACID transporter, TRANSPORTER 1; Solute y+system), carrier family 7, member member 5 5; solute carrier family 7 (cationic amino acid transporter, y+system), member 5 S0705 breast cancer 25855 DKFZp564A063; BRMS1; KARAAVSPQK N/A N/A 1:1000- metastasis breast cancer metastasis- RKSDGP 1:2000 suppressor 1 suppressor 1; breast (403) cancer metastasis suppressor 1 S0706 KiSS-1 3814 MGC39258; KISS1; KiSS-1 RQIPAPQGAV N/A N/A 1:180 metastasis- metastasis-suppressor; LVQREKD suppressor KISS1 METASTIN; malignant (404) melanoma metastasis- suppressor; KISS1 METASTASIS SUPPRESSOR S0708 cofactor 9439 DKFZp434H0117; CRSP133; SVKEQVELIIC N/A N/A 1:2430 required for SUR2; DRIP130; CRSP3; NLKPALK Sp1 trans- mediator; transcriptional (138) criptional co-activator CRSP130; activation, CRSP; 130 KD SUBUNIT; subunit 3, CRSp 130 kD subunit; 130 kDa 133 kDa transcriptional co-activator; 130 kDa transcriptional co- activator; vitamin D3 receptor interacting protein; c S5002 keratin 14 3861 CK; KRT14; K14; EBS4; Antibody obtained from 1:50 (epidermolysis EBS3; cytokeratin 14; Chemicon bullosa CK 14; KERATIN, TYPE I simplex, CYTOSKELETAL 14; Dowling-Meara, keratin 14 (epider- Koebner) molysis bullosa simplex, Dowling-Meara, Koebner) S5003 keratin 17 3782 PCHC1; PC; PC2; 39.1; Antibody obtained from Dako 1:10-1:25 KRT17; K17; CYTOKERATIN 17; VERSION 1; CK 17; KERATIN, TYPE I CYTO- SKELETAL 17 S5004 keratin 18 3875 K18; CYK18; KRT18; CYTO- Antibody obtained from Dako 1:200- KERATIN 18; CK 18; 1:400 KERATIN, TYPE I CYTO- SKELETAL 18 S5005 keratin 18 3875 K18; CYK18; KRT18; CYTO- Antibody obtained from 1:50- KERATIN 18; CK 18; Becton Dickinson 1:100 KERATIN, TYPE I CYTO- SKELETAL 18 S5012 tumor- 4072 TROP1; LY74; Ep-CAM; Antibody obtained from 1:40 associated GA733-2; EGP40; MK-1; Oncogene Research Products calcium signal CO17-1A; EPCAM; M4S1; KSA; (Calbiochem) transducer 1 TACSTD1; EGP; MK-1 antigen; EPITHELIAL CELLULAR ADHESION MOLECULE; GASTROINTESTINAL TUMOR-ASSOCIATED ANTIGEN 2, 35 KD GLYCOPROTEIN; tumor-associated calcium signal transducer 1 precurso S5014 estrogen 2100 ER-BETA; ESR-BETA; ESR2; Antibody obtained from 1:2500 receptor 2 Erb; ESRB; NR3A2; ESTROGEN Oncogene Research Products (ER beta) RECEPTOR, BETA; estrogen (Calbiochem) receptor 2 (ER beta) S5038 mucin 1, 4582 PEMT; MUC1; episialin; Antibody obtained from 1:1 transmembrane EMA; PUM; H23AG; CD227; Imperial Cancer Research PEM; CARCINOMA-ASSOCIATED Technology (ICRT) MUCIN; H23 antigen; TUMOR-ASSOCIATED MUCIN; DF3 antigen; peanut- reactive urinary mucin; mucin 1, transmembrane; polymorphic epithelial mucin; MUCIN 1, URINARY; MUCIN, TUMOR-ASSOCIATE S5044 transferrin 7037 P90; TR; TFRC; TFR; CD71; Antibody obained from 1:20 receptor (p90, T9; TRFR; ANTIGEN CD71; NeoMarkers CD71) TRANSFERRIN RECEPTOR PROTEIN; transferrin receptor (p90, CD71) S5045 v-erb-b2 2064 HER-2; ERBB2; NGL; Antibody obtained from 1:600 erythroblastic P185ERBB2; HER2; C-ERBB-2; NeoMarkers leukemia viral NEU; MLN 19; EC 2.7.1.112; oncogene TKR1 HERSTATIN; NEU PROTO- homolog 2, ONCOGENE; ONCOGENE ERBB2; neuro/gliblas- RECEPTOR PROTEIN-TYROSINE toma derived KINASE ERBB-2 PRECURSOR; oncogene ONCOGENE NGL, NEUROBLAS- homolog TOMA- OR GLIOBLASTOMA- (avian) DERIVED; TYROSINE KINASE- TYPE CELL S5047 major vault 9961 MVP; LRP; VAULT1; LUNG Antibody obtained from 1:300 protein LUNG RESISTANCE-RELATED NeoMarkers PROTEIN; MAJOR VAULT PROTEIN, RAT, HOMOLOG OF S5064 tumor protein 8626 LMS; TP73L; KET; SHFM4; Antibody obtained from Dako 1:50 p73-like p73H; EEC3; TP63; p51; TUMOR PROTEIN p63; TUMOR PROTEIN p73-LIKE; p53- RELATED PROTEIN p63; tumor protein 63 kDa with strong homology to p53 S5065 estrogen 2099 ER; NR3A1; ESR1; Era; ESR; Antibody obtained from Dako 1:20 receptor 1 ER-ALPHA; ESRA; ESTRADIOL RECEPTOR; ESTROGEN RECEPTOR, ALPHA; estrogen receptor 1 (alpha) S5066 v-erb-b2 2064 HER2; ERBB2; NGL; Antibody obtained from Dako 1:300 erythroblastic P185ERBB2; HER2; C-ERBB-2; leukemia viral NEU; MLN 19; EC 2.7.1.112; oncogene TKR1 HERSTATIN; NEU PROTO- homolog 2, ONCOGENE; ONCOGENE ERBB2; neuro/gliblas- RECEPTOR PROTEIN-TYROSINE toma derived KINASE ERBB-2 PRECURSOR; oncogene ONCOGENE NGL, NEUROBLAS- homolog TOMA- OR GLIOBLASTOMA- (avian) DERIVED; TYROSINE KINASE- TYPE CELL S5067 cathepsin D 1509 CTSD; MGC2311; CPSD; EC Antibody obtained from Dako 1:20-1:50 (lysosomal 3.4.23.5; cathespin D aspartyl preporprotein; Cathepsin protease) D precursor; cathespin D (lysosomal aspartyl protease); S5069 CA 125 n/a Antibody obtained from Dako 1:20 S5070 CA 15-3 n/a Antibody obtained from Dako 1:50 S5071 CA 19-9 n/a Antibody obtained from Dako 1:50 S5072 v-myc myelo- 4609 c-Myc; MYC; ONCOGENE MYC; Antibody obtained from Dako 1:50 cytomatosis Myc proto-oncogene viral oncogene protein; PROTOONCOGENE homolog HOMOLOGOUS TO MYELOCYTO- (avain) MATOSIS VIRUS; v-myc myelocytomatosis viral oncogene homolog (avian); v-myc avian myelocytoma- tosis viral oncogene homolog; Avian myelocyto- matosis viral (v-myc) onco S5073 cadherin 1, 999 CDH1; Cadherin-1; Arc-1; Antibody obtained from Dako 1:100- type 1, E- ECAD; CDHE; Uvomorulin; 1:150 cadherin LCAM; Epithelial-cadherin (epithelial) precursor; cell-CAM 120/80; CADHERIN, EPITHELIAL; calcium- dependent adhesion protein, epithelial; cadherin 1, E-cadherin (epithelial); cadherin 1, type 1 preproprotein; cadherin 1, S5074 glutathione S- 2950 GSTP1; DFN7; GSTP1-1; Antibody obtained from Dako 1:50 transferase pi GST3; GSTPP; GST class-pi; glutathione transferase; EC 2.5.1.18; glutathione S-transferase; pi; GST, CLASS PI; deafness, X-linked 7; GLUTATHIONE S- TRANSFERASE 3; GLUTATHIONE S-TRANSFERASE, PI; FAEES3 GLUTATHIONE S-TRANSFERASE PI PSEUD S5075 tumor protein 7157 p53; TP53; TRP53; PHOSPO- Antibody obtained from Dako 1:50 p53 (Li- PROTEIN P53; TRANSFORMA- Fraumeni TION-RELATED PROTEIN 53; syndrome) TUMOR SUPPRESSOR P53; CELLULAR TUNOR ANTIGEN P53; tumor protein p53 (Li-Fraumeni syndrome) S5076 progesterone 5241 NR3C3; PR; PGR; Antibody obtained from Dako 1:50 receptor PROGESTERONE RESISTANCE; PSEUDOCORPUS LUTEUM IN- SUFFICIENCY PROGESTERONE RECEPTOR S5077 trefoil 7031 Antibody obtained from Dako 1:50-1:100 factor 1 (breast cancer, estrogen- inducible sequence expressed in) S5079 enolase 2, 2026 NSE; ENO2; 2-phospho-D- Antibody obtained from Dako 1:400 (gamma, glycerate hydro-lyase; neuronal) ENOLASE, GAMMA; neurone- specific enolase; ENOLASE, NEURON-SPECIFIC; 2- phospho-D-glycerate hydrolyase; EC 4.2.1.11; Neural enolase; enolase-2, gamma, neuronal; neuron specific gamma enolase; enolase 2, (gamma, S5080 B-cell CLL/ 596 BCL2; FOLLICULAR LYMPHOMA; Antibody obtained from Dako 1:50 lymphoma 2 APOPTOSIS REGULATOR BCL-2; B-cell CLL/lymphoma 2; B-cell lymphoma protein 2 alpha; B-cell lymphoma protein 2 beta; ONCOGENE B-CELL LEUKEMIA 2 LEUKEMIA, CHRONIC LYMPHATIC, TYPE 2 S5081 retinoblastoma 5925 p105-Rb; PP110; Retino- Antibody obtained from Dako 1:20 1 (including blastoma-1; RB; RB1; osteosarcoma) RETINOBLASTOMA-ASSOCIATED PROTEIN; RB OSTEOSARCOMA, RETINOBLASTOMA-RELATED; retinoblastoma 1 (including osteosarcoma) S5082 synaptophysin 6855 SYP; Synaptophysin; Major Antibody obtained from Dako 1:50 synaptic vesicle protein P38 S5083 BCL2- 581 BAX; BCL2-associated X Antibody obtained from Dako 1:500 associated X protein; APOPTOSIS protein REGULATOR BAX, MEMBRANE ISOFORM ALPHA S5086 estrogen 2100 ER-BETA; ESR-BETA; ESR2; Antibody obtained from Abcam 1:200 receptor 2 Erb; ESRB; NR3A2; (ER beta) ESTROGEN RECEPTOR, BETA; estrogen receptor 2 (ER beta) S5087 mucin 1, 4582 PEMT; MUC1; episialin; Antibody obtained from Zymed 1:200- transmembrane EMA; H23AG; CD227; PEM; 1:1600 CARCINOMA-ASSOCIATED MUCIN; H23 antigen; TUMOR- ASSOCIATED MUCIN; DF3 antigen; peanut-reactive urinary mucin; mucin 1, transmembrane; polymorphic epithelial mucin; MUCIN 1, URINARY; MUCIN, TUMOR- ASSOCIATE S6001 estrogen 2099 ER; NR3A1; ESR1; Era; ESR; Antibody obtained from U.S. Labs 1:1 receptor 1 ER-ALPHA; ESRA; ESTRADIOL RECEPTOR; ESTROGEN RECEPTOR, ALPHA; estrogen receptor 1 (alpha) S6002 progesterone 5241 NR3C3; PR; PGR; Antibody obtained from U.S. Labs 1:1 receptor PROGESTERONE RESISTANCE; PSEUDOCORPUS LUTEUM INSUFFICIENCY PROGES- TERONE RECEPTOR S6003 v-erb-b2 2064 HER2; ERBB2; NGL; Antibody obtained from U.S. Labs 1:1 erythroblastic P185ERBB2; HER2; C-ERBB-2; leukemia viral NEU; MLN 19; EC 2.7.1.112; oncogene TKR1 HERSTATIN; NEU PROTO- homolog 2, ONCOGENE; ONCOGENE ERBB2; neuro/gliblas- RECEPTOR PROTEIN-TYROSINE toma derived KINASE ERBB-2 PRECURSOR; oncogene ONCOGENE NGL, NEUROBLAS- homolog TOMA- OR GLIOBLASTOMA- (avian) DERIVED; TYROSINE KINASE- TYPE CELL S6004 B-cell CLL/ 596 BCL2; FOLLICULAR LYMPHOMA; Antibody obtained from U.S. Labs 1:1 lymphoma 2 APOPTOSIS REGULATOR BCL-2; B-cell CLL/lymphoma 2; B- cell lymphoma protein 2 alpha; B-cell lymphoma protein 2 beta; ONCOGENE B-CELL LEUKEMIA 2 LEUKEMIA, CHRONIC LYMPHATIC, TYPE 2 S6005 keratin 5 3852 KRT5; EBS2; Keratin-5; K5; Antibody obtained from U.S. Labs 1:1 (epidermolysis CYTOKERATIN 5; CK 5; 58 bullosa KDA CYTOKERATIN; KERATIN, simplex, TYPE II CYTOSKELETAL 5; Dowling-Meara/ keratin 5 (epidermolysis Kobner/Weber- bullosa simplex, Dowling- Cockayne Meara/Kobner/Weber- types) Cockayne types) S6006 tumor protein 7157 p53; TP53; TRP53; PHOSPHO- Antibody obtained from U.S. Labs 1:1 p53 (Li- PROTEIN P53; TRANSFORMA- Fraumeni TION-RELATED PROTEIN 53; syndrome) TUMOUR SUPPRESSOR P53; CELLULAR TUMOR ANTIGEN P53; tumor protein p53 (Li-Fraumeni syndrome) S6007 KI67 n/a Antibody obtained from U.S. Labs 1:1 S6008 epidermal 1956 S7; EGFR; 2.7.1.11; ERBB; Antibody obtained from U.S. Labs 1:1 growth factor ONOGENE ERBB; ERBB1 receptor SPECIES ANTIGEN 7; V-ERB- (erythro- B AVIAN ERYTHROBLASTIC blastic LEUKEMIA VIRAL ONCOGENE leukemia viral HOMOLOG; epidermal growth (v-erb-b) factor receptor (avian oncogene erythroblastic luekemia homolog, viral (v-erb-b) oncogene avian) homolog) S6011 enolase 2, 2026 NSE; ENO2; 2-phospho-D- Antibody obtained from U.S. Labs 1:1 (gamma, glycerate hydro-lyase; neuronal) ENOLASE, GAMMA; neurone- specific enolase; ENOLASE, NEURON-SPECIFIC; 2- phospho-D-glycerate hydrolyase; EC 4.2.1.11; Neural enolase; enolase- 2, gamma, neuronal; neuron specific gamma enolase; enolase 2, (gamma, S6012 thyroid trans- 7080 benign chorea; chorea, Antibody obtained from U.S. Labs 1:1 cription hereditary benign; NK-2 factor 1 (Drosophila) homolog A (thyroid nuclear factor); Thyroid transcription factor 1 (NK-2, Drosophila, homolog of, A); BCH; BHC; TEBP; TTF1; NKX2A; TTF-1; NKX2.1 S6013 v-erb-b2 2064 HER2; ERBB2; NGL; Antibody obtained from U.S. Labs 1:1 erythroblastic P185ERBB2; HER2; C-ERBB-2; leukemia viral NEU; MLN 19; EC 2.7.1.112; oncogene TKR1 HERSTATIN; NEU PROTO- homolog 2, ONCOGENE; ONCOGENE ERBB2; neuro/gliblas- RECEPTOR PROTEIN-TYROSINE toma derived KINASE ERBB-2 PRECURSOR; oncogene ONCOGENE NGL, NEUROBLAS- homolog TOMA- OR GLIOBLASTOMA- (avian) DERIVED; TYROSINE KINASE- TYPE CELL 

1. A method for selecting a chemotherapy for a lung or ovarian cancer patient comprising steps of: providing a cancer sample from a lung or ovarian cancer patient; detecting the presence of expression of TLE3 in the cancer sample; and selecting a taxane or taxane derivative for chemotherapy of the cancer patient when the TLE3 expression is present.
 2. The method of claim 1, wherein the cancer patient has lung cancer.
 3. The method of claim 2, wherein the step of selecting comprises selecting a taxane for chemotherapy.
 4. The method of claim 3, wherein the taxane is paclitaxel.
 5. The method of claim 3, wherein the taxane is docetaxel.
 6. The method of claim 2, wherein the step of detecting comprises steps of: providing a negative control sample; detecting a level of TLE3 expression in the negative control sample; detecting a level of TLE3 expression in the cancer sample; and comparing the level of TLE3 expression in the cancer sample with the level of TLE3 expression in the negative control sample.
 7. The method of claim 2, wherein the step of detecting comprises steps of: providing a positive control sample; detecting a level of TLE3 expression in the positive control sample; detecting a level of TLE3 expression in the cancer sample; and comparing the level of TLE3 expression in the cancer sample with the level of TLE3 expression in the positive control sample.
 8. The method of claim 2, wherein the step of detecting comprises contacting the cancer sample with an interaction partner that binds a TLE3 polypeptide.
 9. The method of claim 3, wherein the step of detecting comprises contacting the cancer sample with an interaction partner that binds a TLE3 polypeptide.
 10. The method of claim 4, wherein the step of detecting comprises contacting the cancer sample with an interaction partner that binds a TLE3 polypeptide.
 11. The method of claim 5, wherein the step of detecting comprises contacting the cancer sample with an interaction partner that binds a TLE3 polypeptide.
 12. The method of claim 8, wherein the interaction partner is an antibody.
 13. The method of claim 9, wherein the interaction partner is an antibody.
 14. The method of claim 10, wherein the interaction partner is an antibody.
 15. The method of claim 11, wherein the interaction partner is an antibody.
 16. The method of claim 2, wherein the step of detecting comprises contacting the cancer sample with one or more primers that hybridize with a TLE3 polynucleotide.
 17. The method of claim 3, wherein the step of detecting comprises contacting the cancer sample with one or more primers that hybridize with a TLE3 polynucleotide.
 18. The method of claim 4, wherein the step of detecting comprises contacting the cancer sample with one or more primers that hybridize with a TLE3 polynucleotide.
 19. The method of claim 5, wherein the step of detecting comprises contacting the cancer sample with one or more primers that hybridize with a TLE3 polynucleotide.
 20. The method of claim 1, wherein the cancer patient has ovarian cancer.
 21. The method of claim 20, wherein the step of selecting comprises selecting a taxane for chemotherapy.
 22. The method of claim 21, wherein the taxane is paclitaxel.
 23. The method of claim 21, wherein the taxane is docetaxel.
 24. The method of claim 20, wherein the step of detecting comprises steps of: providing a negative control sample; detecting a level of TLE3 expression in the negative control sample; detecting a level of TLE3 expression in the cancer sample; and comparing the level of TLE3 expression in the cancer sample with the level of TLE3 expression in the negative control sample.
 25. The method of claim 20, wherein the step of detecting comprises steps of: providing a positive control sample; detecting a level of TLE3 expression in the positive control sample; detecting a level of TLE3 expression in the cancer sample; and comparing the level of TLE3 expression in the cancer sample with the level of TLE3 expression in the positive control sample.
 26. The method of claim 20, wherein the step of detecting comprises contacting the cancer sample with an interaction partner that binds a TLE3 polypeptide.
 27. The method of claim 21, wherein the step of detecting comprises contacting the cancer sample with an interaction partner that binds a TLE3 polypeptide.
 28. The method of claim 22, wherein the step of detecting comprises contacting the cancer sample with an interaction partner that binds a TLE3 polypeptide.
 29. The method of claim 23, wherein the step of detecting comprises contacting the cancer sample with an interaction partner that binds a TLE3 polypeptide.
 30. The method of claim 26, wherein the interaction partner is an antibody.
 31. The method of claim 27, wherein the interaction partner is an antibody.
 32. The method of claim 28, wherein the interaction partner is an antibody.
 33. The method of claim 29, wherein the interaction partner is an antibody.
 34. The method of claim 20, wherein the step of detecting comprises contacting the cancer sample with one or more primers that hybridize with a TLE3 polynucleotide.
 35. The method of claim 21, wherein the step of detecting comprises contacting the cancer sample with one or more primers that hybridize with a TLE3 polynucleotide.
 36. The method of claim 22, wherein the step of detecting comprises contacting the cancer sample with one or more primers that hybridize with a TLE3 polynucleotide.
 37. The method of claim 23, wherein the step of detecting comprises contacting the cancer sample with one or more primers that hybridize with a TLE3 polynucleotide. 